Risultati finali
The project data will be collected according to one or more specific templates depending on the technology TRL etc to be made available by the FCH2 JU in a dedicated platformtool accessible online and passwordprotected
Annual data reporting for 2022The project data will be collected according to one or more specific templates depending on the technology TRL etc to be made available by the FCH2 JU in a dedicated platformtool accessible online and passwordprotected
Annual data reporting for 2023The project data will be collected according to one or more specific template(s) depending on the technology, TRL, etc.) to be made available by the FCH2 JU in a dedicated platform/tool accessible on-line and password-protected.
HYG will design, build, and test (full functional) the integrated electrolyser and fuel cell containers and storage in-house before shipping them to Raggovida. KES will support the task by specifying the interconnecting IT hardware for the plant.
Site readyVK will be responsible for the preparation of the site in Raggovidda. The site will necessarily be located in an area hardly accessible in wintertime, and major construction works will need to be scheduled for summer; VK will build a hall to house the full system, so that work may proceed also in winter. VK will also procure all necessary legal authorisations for the site, and provide suitable heating, internet connection, water supply (extending a previously dug one), and electrical connections to both grid and wind farm. HYG and KES will train VK’s personnel in basic maintenance, safety procedures and general principles of their plant, so that they may promptly intervene in case of minor issues requiring manual intervention on the plant.
Components installed, qualified and verifiedVK will lead the operations for installation and connection of the system, with support from HYG and KES. HYG will be responsible for shipping the components to the site, with VK assisting in complying with customs regulations regarding temporary introduction of the equipment. Tecnalia will monitor the installation process and will evaluate changes to their system design, if the need arises. HYG and KES will qualify and verify their components after installation according to their protocols.
Tecnalia will develop protocols for demonstration to test the control algorithm developed by US and SINTEF for the energy-storage use case. These protocols shall ensure that all relevant aspects of the control algorithms shall be tested during demonstration. Furthermore, Tecnalia will perform a risk analysis for each set of controllers in terms of plant reliability and safety. SINTEF and US will modify their control algorithms according to Tecnalia’s input if necessary. HYG, VK and KES will support the planning phase by quality-checking the protocols before their application in the field.
Engineering study: electrolysers towards MAWP 2023 targetsSINTEF will identify the key challenges to be solved to reach the targets for hydrogen production from renewable electricity set by the FCH JU and its successor in Horizon Europe Drawing on their experience before and during Haeolus SINTEF will evaluate and rank solutions to these challenges with the support of the industrial expertise of HYG SINTEF will include in the study the published state of the art of the electrolyser industry in Europe and worldwide
Six conferences contributions and three journal articles (submitted and not rejected)UBFC US SINTEF and Tecnalia will publish the results of their research activities in international reputable highimpact peerreviewed openaccess journals These partners will also present their results in international toplevel conferences with particular attention to the more industryoriented and to workshops organised by IPHE
Diagnostics and prognostics experience reportAfter the initial deployment, the diagnostic and prognostic module will be continually assessed and fine-tuned with the data produced during the demonstration phase.
Energy analysis of the Raggovidda integrated systemTecnalia will define the overall layout of the plant and, by means of mathematical modelling, the sizing of the components, detailing the high-level system characteristics that will allow the flexible operation of the plant with multiple control strategies during demonstration, also factoring in the wind farm characteristics and the targeted application scenarios.
Field demonstration results with fuel-production strategyUS will be responsible for enacting and following up the demonstration of the plant in fuel-production configuration by means of KES' remote control and monitoring software. US will report any safety-related event to JRC’s HIAD.
Valorisation plan for hydrogen and by-productsSINTEF will chart valorisation opportunities for the hydrogen, oxygen and heat produced by the plant. VK will contribute their local contact network and knowledge of the local economy. SINTEF will contact local authorities and businesses to assess their interest and capability to exploit hydrogen, oxygen and heat and, when appropriate, supporting them in drafting applications for funding of hydrogen demonstration activities with Norwegian or European funding agencies.
Protocols for demonstration of fuel-production strategyTecnalia will develop protocols for demonstration to test the control algorithm developed by US and SINTEF for the fuel-production use case. These protocols shall ensure that all relevant aspects of the control algorithms shall be tested during demonstration. Furthermore, Tecnalia will perform a risk analysis for each set of controllers in terms of plant reliability and safety. SINTEF and US will modify their control algorithms according to Tecnalia’s input if necessary. HYG, VK and KES will support the planning phase by quality-checking the protocols before their application in the field.
Three academic seminars for master and PhD studentsUBFC and US will organise seminars about the project at target master students classes and PhD schools in different countries
Impact of wind-hydrogen plants on energy systems and RCSSINTEF, US and Tecnalia will produce and analyse the potential impact of the Haeolus concept on the European and international energy systems, especially in regard to the penetration of wind power into the energy mix. The report will also consider the implications on regulations, codes and standards in energy systems and wind farms, with the support of HYG and of contacts established in the IPHE.
Environmental performance analysisTecnalia will evaluate the environmental impact of the hydrogen plant in the actual deployment and in the case studies identified in task 5.2. The evaluation will include field experience from VK and data gathered by KES. Tecnalia will conduct a Life-Cycle Assessment with a gate-to-gate perspective.
Field demonstration results with mini-grid strategyUS will be responsible for enacting and following up the demonstration of the plant in mini-grid configuration by means of KES' remote control and monitoring software. US will report any safety-related event to JRC’s HIAD.
Protocols for demonstration of mini-grid strategyTecnalia will develop protocols for demonstration to test the control algorithm developed by US and SINTEF for the mini-grid use case. These protocols shall ensure that all relevant aspects of the control algorithms shall be tested during demonstration. Furthermore, Tecnalia will perform a risk analysis for each set of controllers in terms of plant reliability and safety. SINTEF and US will modify their control algorithms according to Tecnalia’s input if necessary. HYG, VK and KES will support the planning phase by quality-checking the protocols before their application in the field.
Business case analysis for hydrogen in european wind farmsSINTEF will prepare a report for the business case of hydrogen generation within wind farms, detailing and quantifying the opportunities for wind farm operators, the economic advantages and challenges of the technology, and the market outlook depending on the future development of hydrogen technology and wind power penetration, with particular focus on grid balancing services. The analysis will focus on the more relevant markets for wind power in Europe, e.g. Norway, Germany, Spain and Denmark. KES will contribute specifically on the impact of remote control and monitoring on the business model. VK, HYG and Tecnalia will contribute their specific knowledge of their home wind power markets.
Factory acceptance testHYG will demonstrate the control algorithms programmed by SINTEF and US in their laboratory for a limited time span; this demonstration may lead to modifications to the algorithms by SINTEF and US. KES will be responsible for data management and ensuring the relevance of the laboratory demonstration to field operations.
Control performance reportSINTEF will evaluate the performance of control systems for each use case as the data is produced from the demonstration. SINTEF and US will test the control system by appropriate methods, such as for example simulations or X-in-the-loop methods. With these methods, the controlled plant will be tested even in operating conditions not present at the demonstration site, e.g. hydrogen demand, distribution of hydrogen with pipeline, usage of plant waste heat, etc. SINTEF will assess the performance of the control systems, in particular their applicability to other sites (offshore, warmer climates, etc.) and, with the support of US, will suggest improvements to the control algorithms and guidelines for future work; if possible, these will be tested within Haeolus.
Techno-economic analysis of wind-hydrogen integrationTecnalia will evaluate the applicability of the design in other conditions, and suggest modifications for similar plants in different kinds of wind farms (e.g. offshore, single-turbine, large farms, etc.), considering at least three case studies from actual wind farms. SINTEF will support the task in the socio-economic evaluation of such plants, their profitability and their potential for job creation and effect on local and national economies. SINTEF shall also report on the applicable regulations, codes and standards for such applications for all case studies identified by Tecnalia.
Field demonstration results with energy-storage strategyUS will be responsible for enacting and following up the demonstration of the plant in energy-storage configuration by means of KES' remote control and monitoring software. US will report any safety-related event to JRC’s HIAD.
UBFC will arrange a visit to the plant during demonstration for interested parties including politicians industry nongovernmental organisations with the logistic support of VK
Project presented at international industrial fairUBFC, with the support of HYG, will organise a presence at a relevant fair (e.g. the Hanover Fair) towards the end of the project, to showcase its results to an industrial and decision-making audience.
Real-time demonstration data available on the Web siteThrough the Web site KES will visualise the operation of the plant based on realtime data during the demonstration phase
Web site online, presence in selected social networksKES will set up a Web site for the project. The Web site will feature project description and progress, contact information, public deliverables, open-access journal articles, presentations and relevant news items for the field of wind-hydrogen systems. KES will also establish a presence on relevant social media, such as LinkedIn, Twitter, YouTube, and add content regularly through the project.
UBFC will organise a workshop during the early stages of the project, directed at both research and industry, to disseminate the early results in system design and establish connections with other initiatives. The workshop will preferably be organised in connection with a relevant international scientific conference.
Control system for mini-grid use caseUS will develop high-level control algorithms for the integrated wind-hydrogen system for the use case of mini-grid.
Control system for energy-storage use caseUS will develop high-level control algorithms for the integrated wind-hydrogen system for the use case of energy storage.
Control system for fuel-production use caseUS will develop high-level control algorithms for the integrated wind-hydrogen system for the use case of fuel production.
Student internship on-siteUBFC and US will organise one internship onsite for a doctoral or master student
Diagnostics and prognostics for the wind-hydrogen plantUBFC will develop relevant diagnostic and prognostic systems to assess the current state and maintenance requirements of all critical components (electrolyser, compressor, …), to feed the controller and to anticipate maintenance requirements of all critical components so that the system may be operated for months without supervision in person.
Dynamic model for hydrogen production and storage plantsUS will develop a library of static and dynamic process models of the system components. The model will include actual constraints, such as working ranges of components, capacity limits of power the lines, dynamic output of wind turbines, dynamics and ramping rates. SINTEF will integrate the resulting model library into a fully integrated system, and support US to ensure that the model library is the best trade-off between accuracy, computational performance and complexity for the purpose of control synthesis and analysis.
Pubblicazioni
Autori:
Muhammad Bakr Abdelghany, Muhammad Shehzad, Valerio Mariani, Luigi Glielmo
Pubblicato in:
World Hydrogen Energy Conference, 2022
Editore:
WHEC2020
Autori:
Federico Zenith
Pubblicato in:
Next Generation Electrolysers Conference, 2020
Editore:
Next Generation Electrolysers Conference
DOI:
10.5281/zenodo.4316974
Autori:
Zenith, Federico
Pubblicato in:
Hydrogen Production in the Arctic seminar, Numero 26/10/2022, 2022
Editore:
SINTEF
DOI:
10.5281/zenodo.7318643
Autori:
Zenith, Federico
Pubblicato in:
2022
Editore:
SINTEF
DOI:
10.5281/zenodo.7318642
Autori:
Zenith, Federico
Pubblicato in:
2021
Editore:
SINTEF
DOI:
10.5281/zenodo.4542919
Autori:
Zenith, Federico
Pubblicato in:
2019
Editore:
Fuel Cells & Hydrogen Joint Undertaking
DOI:
10.5281/zenodo.3553686
Autori:
Zenith, Federico
Pubblicato in:
2019
Editore:
SINTEF
DOI:
10.5281/zenodo.3339180
Autori:
Federico Zenith
Pubblicato in:
Hydrogensone Arktis, 2020
Editore:
Troms & Finnmark County Council
DOI:
10.5281/zenodo.3675350
Autori:
Zenith, Federico
Pubblicato in:
Numero 25/10/2022, 2022
Editore:
SINTEF
DOI:
10.5281/zenodo.7318621
Autori:
Muhammad Bakr Abdelghany, M. F Shehzad, Davide Liuzza, Valerio Mariani, Luigi Glielmo
Pubblicato in:
59th IEEE Conference on Decision and Control, 2020
Editore:
59th IEEE Conference on Decision and Control
DOI:
10.5281/zenodo.4420338
Autori:
Zenith, Federico
Pubblicato in:
2021
Editore:
Haeolus project
DOI:
10.5281/zenodo.5052781
Autori:
Federico Zenith
Pubblicato in:
Nordic Hydrogen & Fuel Cell Conference, 2018
Editore:
Nordic Hydrogen & Fuel Cell Conference
DOI:
10.5281/zenodo.1460454
Autori:
Federico Zenith
Pubblicato in:
IEA HIA Task 38 5th Plenary Meeting, 2018
Editore:
IEA HIA Task 38
Autori:
Federico Zenith
Pubblicato in:
Input meeting for Svalbard's future energy supply, 2018
Editore:
Norway's Ministry for Oil and Energy
DOI:
10.5281/zenodo.1482894
Autori:
Federico Zenith
Pubblicato in:
Workshop on Power-to-X Demonstrations, 2018
Editore:
IEA HIA Task 38
DOI:
10.5281/zenodo.1493992
Autori:
Roche, Robin
Pubblicato in:
Journées du GdR SEEDS-JCGE, 2019
Editore:
CNRS
DOI:
10.5281/zenodo.3241265
Autori:
Federico Zenith
Pubblicato in:
Hydrogen i Vinden, 2019
Editore:
SINTEF
DOI:
10.5281/zenodo.2605260
Autori:
Vibeke S. Nørstebø, Miguel Muñoz Ortiz, Gerardo A. Perez-Valdes
Pubblicato in:
30th European Conference on Operational Research (EURO2019), 2019
Editore:
UCD
DOI:
10.5281/zenodo.3669909
Autori:
Christian Bue
Pubblicato in:
Hydrogen i Vinden, 2019
Editore:
Varanger Kraft
DOI:
10.5281/zenodo.2607649
Autori:
Steffen Møller-Holst
Pubblicato in:
Hydrogen i Vinden, 2019
Editore:
SINTEF
DOI:
10.5281/zenodo.2605540
Autori:
Federico Zenith
Pubblicato in:
2019
Editore:
SINTEF
DOI:
10.5281/zenodo.3465528
Autori:
Federico Zenith
Pubblicato in:
Microgrids Summer School, 2019
Editore:
FCLAB
DOI:
10.5281/zenodo.3267293
Autori:
Muhammad Faisal Shehzad, Muhammad Bakr Abdelghany, Davide Liuzza, Luigi Glielmo
Pubblicato in:
2019 18th European Control Conference (ECC), 2019, Pagina/e 1896-1901, ISBN 978-3-907144-00-8
Editore:
IEEE
DOI:
10.23919/ecc.2019.8795937
Autori:
Robin Roche
Pubblicato in:
European Control Conference 2019, 2019
Editore:
IEEE
Autori:
Maider Santos-Mugica
Pubblicato in:
International Summit on the Operational Analysis of Wind Farms, 2020
Editore:
International Summit on the Operational Analysis of Wind Farms
DOI:
10.5281/zenodo.4288932
Autori:
Nørstebø, Vibeke Stærkebye; Muñoz Ortiz, Miguel; Perez-Valdes, Gerardo A.
Pubblicato in:
30th European Conference on Operational Research, Numero 23-26/06/2019, 2019
Editore:
SINTEF
DOI:
10.5281/zenodo.3669908
Autori:
Meiling Yue, Zhongliang Li, Robin Roche, Samir Jemei, Noureddine Zerhouni
Pubblicato in:
2020 Prognostics and Health Management Conference (PHM-Besançon), 2020, Pagina/e 122-127, ISBN 978-1-7281-5675-0
Editore:
IEEE
DOI:
10.1109/phm-besancon49106.2020.00026
Autori:
Federico Zenith; Martin Nord Flote; Maider Santos-Mugica; Corey Scott Duncan; Valerio Mariani; Claudio Marcantonini
Pubblicato in:
2023
Editore:
ZSW-BW
DOI:
10.5281/zenodo.8389349
Autori:
Zenith, Federico
Pubblicato in:
2022
Editore:
Alaska Center for Energy and Power
DOI:
10.5281/zenodo.6468199
Autori:
Muhammad Bakr Abdelghany; Valerio Mariani; Davide Liuzza; Oreste Riccardo Natale; Luigi Glielmo
Pubblicato in:
IEEE Transactions on Automation Science and Engineering, 2024, ISSN 1545-5955
Editore:
Institute of Electrical and Electronics Engineers
DOI:
10.1109/tase.2023.3292029
Autori:
Yue, Meiling; Lambert, Hugo; Pahon, Elodie; Roche, Robin; Jemeï, Samir; Hissel, Daniel
Pubblicato in:
Renewable and Sustainable Energy Reviews, 2021, ISSN 1364-0321
Editore:
Elsevier BV
DOI:
10.1016/j.rser.2021.111180
Autori:
Muhammad Bakr Abdelghany, Muhammad Faisal Shehzad, Valerio Mariani, Davide Liuzza, Luigi Glielmo
Pubblicato in:
International Journal of Hydrogen Energy, Numero 47, 2022, Pagina/e 32202-32222, ISSN 0360-3199
Editore:
Pergamon Press Ltd.
DOI:
10.1016/j.ijhydene.2022.07.136
Autori:
Yue, Meiling; Li, Zhongliang; Roche, Robin; Jemeï, Samir; Zerhouni, Noureddine
Pubblicato in:
Control Engineering Practice, Numero 118, 2022, Pagina/e 104959, ISSN 0967-0661
Editore:
Pergamon Press Ltd.
DOI:
10.1016/j.conengprac.2021.104959
Autori:
Muhammad Faisal Shehzad, Muhammad Bakr Abdelghany, Davide Liuzza, Valerio Mariani, Luigi Glielmo
Pubblicato in:
Inventions, Numero 4/4, 2019, Pagina/e 57, ISSN 2411-5134
Editore:
MDPI
DOI:
10.3390/inventions4040057
Autori:
Muhammad Bakr Abdelghany; Muhammad Faisal Shehzad; Davide Liuzza; Valerio Mariani; Luigi Glielmo
Pubblicato in:
International Journal of Hydrogen Energy, Numero 57, 2021, Pagina/e 29297-29313, ISSN 0360-3199
Editore:
Pergamon Press Ltd.
DOI:
10.1016/j.ijhydene.2021.01.064
Autori:
Federico Zenith; Luigi Glielmo; Valerio Mariani
Pubblicato in:
energies, Numero 15, 2022, Pagina/e 6307, ISSN 1996-1073
Editore:
Multidisciplinary Digital Publishing Institute (MDPI)
DOI:
10.3390/en15176307
Autori:
Muhammad Bakr Abdelghany; Valerio Mariani; Davide Liuzza; Luigi Glielmo
Pubblicato in:
International Journal of Hydrogen Energy, 2024, ISSN 0360-3199
Editore:
Pergamon Press Ltd.
DOI:
10.1016/j.ijhydene.2023.08.056
Autori:
Federico Zenith; Martin Nord Flote; Maider Santos-Mugica; Corey Scott Duncan; Valerio Mariani; Claudio Marcantonini
Pubblicato in:
International Journal of Hydrogen Energy, Numero 47, 2022, Pagina/e 35541-35552, ISSN 0360-3199
Editore:
Pergamon Press Ltd.
DOI:
10.1016/j.ijhydene.2022.08.152
Autori:
Andrenacci, Sara; Choi, Yejung; Raka, Yash; Talic, Belma; Colmenares-Rausseo, Luis
Pubblicato in:
2022
Editore:
SINTEF
DOI:
10.5281/zenodo.7144913
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