Stockage d’énergie :Stockage solaire à bord du substrat de la cellule solaire ou sur film flexible, Transport, Distribution et Gestion de route intelligente & Smart city. La combinaison de la conversion et le stockage de l'énergie solaire (énergie solaire et les appareils sans fil à l'aide du stockage solaire sur substrat de la cellule).
Stockage d’énergie :Stockage solaire à bord du substrat de la cellule solaire ou sur film flexible, Transport, Distribution et Gestion de route intelligente & Smart city. La combinaison de la conversion et le stockage de l'énergie solaire (énergie solaire et les appareils sans fil à l'aide du stockage solaire sur substrat de la cellule).
Green Giraffe's Managing Director is Jérôme GUILLET. As Managing Director, Guillet oversees operations and management at Green Giraffe. This short document provides the name and title of Green Giraffe's Managing Director.
World Renewable Energy Congress Presentation wren at council denver 2010Ali Sayigh
The document summarizes the activities of the World Renewable Energy Network (WREN) Council since 2010, including conferences held and future meetings planned. It introduces new council members and provides an agenda for an upcoming lunch meeting covering recent WREN activities, future meetings and congresses, and any other points. The document also announces an upcoming world renewable energy congress in London in 2014 and calls for abstracts and papers on renewable energy topics.
Quality and standards for renewable energyfboshell
The International Renewable Energy Agency (IRENA) works towards a sustainable and widespread deployment of renewable energy technologies. Quality assurance and standardization play a key role in transitioning towards innovative and sustainable energy technologies, by strengthening rapidly growing markets and facilitating trading of renewable energy technologies. IRENA’s study from 2013 in this field, the first one ever focused on renewable energy technologies, shows that quality and standardization are crucial in global technology value chains matching producers and user in opposite places in the world by harmonizing processes, allowing comparability of contracts, and decreasing uncertainty. Also that assured quality, in conformity with sound standards, mitigates technical risks therefore attracting major investments and increasing the trust in the technology by financial sources and public. Quality assurance and conformity with sound standards enables long lasting technological solutions by reducing the replacements to be done in technological plants and equipment and thus, reinvesting the capital that would be aimed at repairing infrastructure to accelerate the deployment of the technology. Quality reinforces the reliability on RET markets and this highly contributes to spread awareness about RET achievements and fulfilment of energy needs.
IRENA is finalizing its study on quality assurance mechanisms for small wind turbines and solar water heaters. The study, undertaken in cooperation with a number of national and regional experts, will provide guidance and recommendation on how countries can implement national quality mechanisms, adapted to their national context, to support growing markets for these technologies.
Emmanuel Brochard is the VP of Business Development for North America and the Caribbean at DCNS, a company that invests in four types of marine renewable energies: tidal turbines, ocean thermal energy conversion (OTEC), floating offshore wind, and wave energy. DCNS provides equipment, installation, and maintenance services for renewable energy projects. Remote island communities in particular can benefit from OTEC, as it provides a stable source of renewable energy to power their isolated grids. DCNS is working on the NEMO project, which will be the first commercial offshore OTEC plant operating in Martinique by 2019, as well as onshore hybrid power plants that can produce electricity, fresh water, and air conditioning.
This document discusses the political challenges of expanding electricity grids to accommodate increasing renewable energy. It argues that electric utility companies, with vested interests in the status quo, often oppose grid expansions that facilitate greater renewable integration. This resistance can slow the energy transition. The document also examines grid and policy issues in Germany, Japan, China, and considers implications for New Zealand's renewable targets.
Ocean currents are influenced by many factors including differences in water density. For example, the Gulf Stream originates in the Gulf of Mexico and flows northeast, influencing climate as part of the global ocean conveyor belt. Ocean currents transfer heat around the world via this conveyor belt and affect both ocean and land temperatures, impacting global weather patterns and climates.
BERTIN TECHNOLOGIES, une filiale du Groupe CNIM, s’appuie sur sa longue expérience d’ingénierie d’innovation pour développer, produire et commercialiser dans le monde entier des systèmes et des équipements innovants. La société intervient dans quatre grands domaines : systèmes et instrumentation, conseil et ingénierie, avec une activité importante consacrée à la gestion des risques et à l'ergonomie, technologies de l’information et enfin pharma et biotechs.
Green Giraffe's Managing Director is Jérôme GUILLET. As Managing Director, Guillet oversees operations and management at Green Giraffe. This short document provides the name and title of Green Giraffe's Managing Director.
World Renewable Energy Congress Presentation wren at council denver 2010Ali Sayigh
The document summarizes the activities of the World Renewable Energy Network (WREN) Council since 2010, including conferences held and future meetings planned. It introduces new council members and provides an agenda for an upcoming lunch meeting covering recent WREN activities, future meetings and congresses, and any other points. The document also announces an upcoming world renewable energy congress in London in 2014 and calls for abstracts and papers on renewable energy topics.
Quality and standards for renewable energyfboshell
The International Renewable Energy Agency (IRENA) works towards a sustainable and widespread deployment of renewable energy technologies. Quality assurance and standardization play a key role in transitioning towards innovative and sustainable energy technologies, by strengthening rapidly growing markets and facilitating trading of renewable energy technologies. IRENA’s study from 2013 in this field, the first one ever focused on renewable energy technologies, shows that quality and standardization are crucial in global technology value chains matching producers and user in opposite places in the world by harmonizing processes, allowing comparability of contracts, and decreasing uncertainty. Also that assured quality, in conformity with sound standards, mitigates technical risks therefore attracting major investments and increasing the trust in the technology by financial sources and public. Quality assurance and conformity with sound standards enables long lasting technological solutions by reducing the replacements to be done in technological plants and equipment and thus, reinvesting the capital that would be aimed at repairing infrastructure to accelerate the deployment of the technology. Quality reinforces the reliability on RET markets and this highly contributes to spread awareness about RET achievements and fulfilment of energy needs.
IRENA is finalizing its study on quality assurance mechanisms for small wind turbines and solar water heaters. The study, undertaken in cooperation with a number of national and regional experts, will provide guidance and recommendation on how countries can implement national quality mechanisms, adapted to their national context, to support growing markets for these technologies.
Emmanuel Brochard is the VP of Business Development for North America and the Caribbean at DCNS, a company that invests in four types of marine renewable energies: tidal turbines, ocean thermal energy conversion (OTEC), floating offshore wind, and wave energy. DCNS provides equipment, installation, and maintenance services for renewable energy projects. Remote island communities in particular can benefit from OTEC, as it provides a stable source of renewable energy to power their isolated grids. DCNS is working on the NEMO project, which will be the first commercial offshore OTEC plant operating in Martinique by 2019, as well as onshore hybrid power plants that can produce electricity, fresh water, and air conditioning.
This document discusses the political challenges of expanding electricity grids to accommodate increasing renewable energy. It argues that electric utility companies, with vested interests in the status quo, often oppose grid expansions that facilitate greater renewable integration. This resistance can slow the energy transition. The document also examines grid and policy issues in Germany, Japan, China, and considers implications for New Zealand's renewable targets.
Ocean currents are influenced by many factors including differences in water density. For example, the Gulf Stream originates in the Gulf of Mexico and flows northeast, influencing climate as part of the global ocean conveyor belt. Ocean currents transfer heat around the world via this conveyor belt and affect both ocean and land temperatures, impacting global weather patterns and climates.
BERTIN TECHNOLOGIES, une filiale du Groupe CNIM, s’appuie sur sa longue expérience d’ingénierie d’innovation pour développer, produire et commercialiser dans le monde entier des systèmes et des équipements innovants. La société intervient dans quatre grands domaines : systèmes et instrumentation, conseil et ingénierie, avec une activité importante consacrée à la gestion des risques et à l'ergonomie, technologies de l’information et enfin pharma et biotechs.
Armorgreen est une société française qui offre une des palettes les plus larges de solutions dans le domaine des énergies renouvelables et plus particulièrement dans le domaine du solaire photovoltaïque.
Implantée en bordure du Rhône, sur la commune de Creys-Mépieu (Isère), la centrale de Creys-Malville appartenait à la filière des réacteurs à neutrons rapides refroidis au sodium (RNR). Elle est définitivement à l'arrêt depuis février 1998.
Après le déchargement complet du combustible (1999-2003), le démantèlement de la salle des machines a été effectué en 2003-2004.
Plusieurs éléments non requis pour la sûreté de l'installation ont également été démontés depuis la mise à l'arrêt de la centrale. Les plus visibles ont été les cheminées, les pylônes et les lignes électriques.
Divers chantiers de déconstruction proprement dite se déroulent régulièrement à l'intérieur des bâtiments, comme par exemple dans les générateurs de vapeur ou le bâtiment réacteur.
Le site a franchi aujourd'hui une nouvelle étape : le traitement des 5 500 tonnes de sodium (utilisé pour transporter la chaleur du cœur du réacteur vers les générateurs de vapeur) dans l'installation TNA.
La déconstruction complète de Superphénix est autorisée par le décret du 20 mars 2006. Ce même jour, un second décret autorisait EDF à exploiter jusqu'en 2035 l'APEC (Atelier pour l'Entreposage du Combustible), dans lequel est entreposé le combustible usé et neuf de Superphénix, ainsi que divers composants issus du démantèlement du réacteur.
Dominique MINIERE, Directeur Délégué Direction Production Ingénierie d'EDF, Vice-président de la SFEN
Présentation lors d’une table ronde sur les grands investissements à venir sur le Parc Nucléaire, les Renouvelables et le Réseau électrique à la convention SFEN du 4 avril 2013. Retrouvez la vidéo de la conférence à la fin de la présentation ou sur youtube.
http://youtu.be/NtAzt8DCnJo
Éolien Offshore - Opportunités pour les entreprises wallonnes en mer du Nord ...Cluster TWEED
Découvrez les présentations des divers orateurs (SOCOFE, SRIW, Otary, Elia, John Cockerill, MecaTech, TWEED), réalisées le 11 octobre 2022, lors d'un événement dédié à l'éolien offshore et aux opportunités pour les entreprises wallonnes en mer du Nord.
Back to the Future of Energy - Session 2 - Stockage mutualise - 11.04.2023Cluster TWEED
Vous avez été près d'une centaine de participants à suivre en ligne ce second épisode de la saga Back to the Future of Energy !
Programme
* Appel à projets Usine - Stockage - 50 M€ du 6/04/23 - Wallonie Entreprendre, Damien Leduc, développeur de projets
* Des modèles collectifs à déployer - BSTOR, Pierre Bayart, Managing Director
* Hub de stockage & mobilité intégrée pour les industriels - John Cockerill, Pierre Garsoux, Eng. Integrated Renewable Solutions
* Solutions DC innovantes pour intégration ER - CE+T, Daniel Rixhon, Business Development
présentation de SENR dans le cadre de la Mission exploratoire AWEX-WBI. Cap sur les Villes intelligentes françaises. (Volet Bordeaux-Nantes: du 23 au 27 novembre 2015).
Propulsion de navire de pêche à l'hydrogène projet filhypyneInterconsulaire 909
Dans le cadre du colloque de l'ORT le 18 juin 2015 à la CCI, labellisé TRIA, retrouvez le projet porté avec la Mission Hydrogène, la COREPEM, l'ENSM pour développer un prototype de navire de pêche propulsé à la PAC hydrogène.
Similaire à 24 christian cermelli - principle power (20)
Allard van Hoeken is the Head of New Energy at Blue Water Services, a company with over 35 years of experience in marine engineering and operating permanently moored systems including FPSOs, SPMs, and tidal energy. Blue Water is developing modular BlueTEC tidal energy platforms that are fully transportable by container and can generate between 100 kW and 2-3 MW of power. The platforms offer a complete package that includes the platform, turbine, controls, power cable, mooring system, and transport to any container port worldwide for projects in remote locations.
Joaquin Brito is the manager of PLOCAN, a test site for marine renewable energy in the Canary Islands. The Canary Islands face challenges associated with island living including limited resources, high energy prices due to reliance on imported fossil fuels, and small electricity generation. However, the islands are early adopters of ocean energy converters due to their location with strong Atlantic swell in the north and offshore wind potential in the south. PLOCAN provides a test site to develop marine renewable technologies and address the island's energy challenges.
Sustainable Marine Energy's commercially viable tidal energy platform, PLAT-O, uses an integrated system approach and low-cost operations to provide a solution to levelized cost of energy concerns. The 100 kW PLAT-O #1 supports site development, is being built and deployed by SME, and will undergo phased testing at EMEC in Orkney, with the goal of five PLAT-O arrays installed between 2015-2017.
The document discusses plans for the Swansea Bay Tidal Lagoon in Wales. It would have a 9.5 km wall that creates an 11.5 km2 lagoon area with an installed capacity of 320 MW. It could generate around 500 GWh annually and reduce CO2 emissions by 236,000 tonnes per year over its 120 year design life. Six similar lagoons in the UK could generate 30 TWh annually, providing 8% of the country's electricity and powering 30% of UK homes. Tidal power has significant untapped potential around the world, with over 313 GW identified globally so far.
Tocardo is a Netherlands-based tidal and river turbine manufacturer and UK-based project developer with proven tidal technology. They have experience developing commercial tidal projects in several countries including the UK, Ireland, Canada, Netherlands, Nepal, Japan, Korea, and others. Some of their current projects include a 2 MW array installed in Canada in 2015, a 6-year track record with 4 turbines installed in the Netherlands, selling 4 turbines and installing them in Nepal with plans for 40 more by 2019, and negotiating contracts for off-grid projects in remote communities in Canada.
41 chris campbell - marine renewable canadajohannaparans
This document discusses Canada's Bay of Fundy as a critical location for developing marine renewable energy at an industrial scale. It outlines Canada's progress and contribution to the pathway toward commercializing tidal energy. Key points include Canada having supportive legislation and infrastructure like FORCE to facilitate early commercial deployments. The goal is a staged 300MW prototype project by 2020-2025 to demonstrate tidal energy can meet market needs for cost, scale, and reliability. Both large industrial projects and smaller community-scale deployments are seen as important to fully demonstrate tidal energy solutions.
Simply Blue Energy is developing a 10MW wave farm at Wave Hub in Cornwall, UK in 2016 using Seabased technology. Simply Blue Energy is an Irish company active in the UK market and specializes in wave energy projects using the Seabased AB technology, a Swedish company that focuses on modular, electrically engineered wave energy converters assembled on an automotive-style line. The Wave Hub site offers a pre-consented location for validating Simply Blue Energy's first project.
This document provides an overview and update on Carnegie Wave Energy's Perth Wave Energy Project in Western Australia. Key points include:
- The project involves 3 CETO 5 wave energy conversion units installed near Garden Island to provide power to the grid and desalinated water to nearby naval facilities. Over 8,500 hours of operation to date.
- The first CETO unit was recently retrieved for onshore inspection and maintenance, validating the maintenance methodology. The remaining 2 units will be retrieved over winter.
- Performance of the CETO units and system has been as expected across a range of sea states up to 5.7m. Power output has been measured and matched models.
- Plans and timelines are
The document summarizes information about Wello Oy's wave energy converter called the Penguin. The Penguin encapsulates a rotating eccentric mass within a single floating hull that directly drives an electricity generator from the motion of ocean waves. It has no hydraulics, joints, or gears. The Penguin is constructed using shipyard manufacturing and off-the-shelf components for scalability. It is installed by towing it on site and connecting it to moorings and the electricity grid, which can be done efficiently in 3-5 days. All of its components are contained inside the hull, allowing for maintenance and replacement to be done on site using a small boat.
Erkki Kasanen of AW-Energy Oy presented information on their WaveRoller wave energy technology. The WaveRoller is a near-shore oscillating wave surge converter that has undergone prototyping from 2002-2014 in Finland and Portugal. A 300 kW demonstration power plant with three 100 kW units was grid connected in Portugal from 2012-2014 and had its performance validated by DNV-GL, positioning the WaveRoller at the forefront of wave energy. Recent projects include cooperation with companies on a demonstration project in France, an upcoming 1.5MW dry test facility, independent performance validation by DNV-GL in line with expectations, being selected as a finalist for a wave project in Portugal, receiving
David Wotherspoon is the Operations Director at SeaRoc. The document discusses several challenges for offshore wind farm operations and maintenance (O&M) including weather downtime, component reliability data sharing, predictive failure modeling, and access issues for larger and further offshore installations. It proposes solutions like whole-life asset management, maximizing power generation and accessibility, innovation in drone inspections and sea access systems, and cooperative planning and contracting across industry portfolios to improve efficiency and reduce costs and downtime. The overall message is that O&M costs can be reduced through collaborative solutions, reliability focused design, improved monitoring and planning, and prioritizing accessibility and uptime over lowest initial costs.
- The document discusses a new offshore wind turbine design called the SCD 8.0 MW nezzy concept that aims to reduce levelized cost of energy (LCoE) through lower capital and operating expenditures.
- Key aspects of the design include a two-bladed downwind floating turbine supported by guyed towers, which eliminates the need for an expensive yaw system. It also allows for easier installation and maintenance using lighter components.
- Analysis shows the SCD 8.0 MW nezzy concept could achieve a 1.4 euro cent per kWh operations and maintenance cost, over 20% lower than current offshore wind farms, through reduced downtime, remote monitoring, and extended maintenance intervals of 5 years. This helps
4. WindFloat et Principle Power, un peu d’histoire
2003
Création de MI&T par
Dr. Dominique Roddier
et Christian Cermelli
2003
Invention du
MiniFloat, le
prédécesseur du
WindFloat
2007
Création de PPI
Développement du
WindFLoat- Brevets
2010
ABS: Approval in
Principle (Certification)
et Labelisation pôle
mer PACA
2011
Mise à I’eau de WF1
Au Portugal
Retrait prévu 2016
2012
Ouverture du bureau
Français, MI&T Europe
Aix-en- Provence
6 Employés
2014
Fusion de MI&T et PPI
CEO Transition
2015
Création de
Principle Power France:
“PPF”
4
5. 5
Technologie WindFloat
•Caractéristiques principales
1. Compatible toutes turbines
2. Ballast actif en circuit fermé
3. Tirant d’eau ajustable par lestage
4. Plaques anti-roulis (stabilité dynamique)
•Avantages de la technologie
• Excellente stabilité statique et dynamique permet
d’utiliser les modèles de turbines commerciales
existantes sans modification
• Opérations en mer fortement simplifiées, utilisant des
bateaux de petite taille disponibles en grand nombre
chez les installateurs d’ancrages
• Pas d’études géotechniques – campagne géophysique
suffisante pour le type d’ancres utilisées
• Réparations de la turbine à terre possible aisément
grace au concept de « plug-and-play »
• Démantelement très simple
• Large portion de « contenu local »
1
3
2
4
6. Prototype à taille réelle (Vestas 2MW) installé
au Portugal depuis 2011 a permis de valider:
1. Modèle économique pour la fabrication et
l’installation du WindFloat
2. La capacité de production dans les conditions de
« tempête 1 an » (7m Hs) sans détérioration de la
courbe de puissance – 14GWh produits
3. La survie dans les tempêtes d’hiver en Atlantique,
jusqu’à 9m Hs, 18m Hmax
4. Résistance à la fatigue induite par les houles et vents
5. Possibilité d’exécuter les taches d’O&M sur la
plateforme
6. Opération du système de ballast actif ainsi que
l’ensemble des autres systèmes et équipements
7. Corréler modèles numériques et réponses du
système
Les Objectifs du Prototype WF1
6
8. => Réduction considérable des
couts de l’énergie à travers:
- Extension de durée de vie (x5)
- Turbines plus grandes(x3-4)
- Flotteur plus petit en
proportion
- Optimisations structurelles
- Amélioration des équipements
- Amélioration de l’accessibilité
- Amélioration de l’ancrage
- Amélioration de la procédure
d’installation
WindFloat II: évolution de la technologie pour fermes pilotes
8