Mois: mai 2013
Prof Dr He Qingcheng, Director of CCOP Technical Secretariat; Dr R.
See on www.globalccsinstitute.com
The university’s Advanced Structures and Composites Centre has won the first round of a potential $93.2 million deepwater offshore wind demonstration project
University of Maine wins first stage of floating offshore wind demonstration competition
The competition for the project was organised by the US Department of Energy (DOE) and the UMaine Composites Centre is one of five awardees chosen from over 70 competing proposals. The initial phase will allocate up to $4 million to each project in order to complete the engineering, design and permitting phase of the award. A year forward the DOE will select three of the five projects for follow-on phases concerned with siting, construction and installation. The overall aim is to achieve commercial operation by 2017.
“We are pleased that the DOE has selected our team’s program after a rigorous technical review” said Dr. Habib Dagher, P.E., director of the Advanced Structures and Composites Center and principal investigator for the project. “This R&D program could be transformational for our state, and will help us demonstrate a unique, patent-pending floating wind turbine technology called VolturnUS.”
The project is known as Aqua Ventus I and will be a 12MW demonstration wind park using the VolturnUS floating platform technology developed at UMaine over the last four years. It builds on the success of the DeepCwind Consortium Research Program which was similarly spearheaded by the UMain Composites Centre and industry partners, funded by DOE, the National Science Foundation-Partnerships for Innovation and the Maine Technology Institute, among others. A 1:8-scale VolturnUS floating platform will be deployed by UMaine researchers at the UMaine Deepwater Offshore Wind Test Site near Monhegan Island, Maine.
UMaine’s Composites Center has entered into a partnership with industry leaders who will collectively invest over $40 million in the project. This will help to de-risk the VolturnUS floating platform in order to generate more private capital for the construction of larger commercial wind farms.
“The United States has tremendous untapped clean energy resources” said U.S. Secretary of Energy Steven Chu, “and it is important for us to develop technologies that will allow us to utilize those resources in ways that are economically viable. Today’s announcement of awards to the first offshore wind projects in the U.S. paves the way to a cleaner, more sustainable and more diverse domestic energy portfolio that develops every source of American energy.”
The advantage of deepwater floating offshore wind farms is that they can potentially harness stronger and more consistent wind resources located beyond the reach of traditional fixed-foundation platforms while being out of sight from the shore. The Gulf of Maine alone has a 156.6 GW offshore wind potential, the majority of which is in deepwater. The state is aiming to construct around 5,000MW of floating farms by 2030, attracting $20 billion of private capital to the state and creating thousands of jobs.
add your insight…
See on www2.umaine.edu
The Odds of Disaster: An Economist’s Warning on Global Warming
See on www.pbs.org
We’re like in a Shrek movie, the one where we are in Far Far Away country… because it is far…far…away.
That’s current position of CCS in Europe, in "far far away" country
See on www.e3g.org
See on papagaio-pnr.blogspot.com.br
Carbon Capture and Storage Technologies Research at MIT Lab for Energy and the Environment (LFEE) and Carbon Sequestration Initiative
See on sequestration.mit.edu
Effective and Sustainable Hydraulic Fracturing. Edited by: Andrew P. Bunger, John McLennan and Rob Jeffrey. ISBN 978-953-51-1137-5, Published 2013-05-17
This book comprises the proceedings for the International Conference for Effective and Sustainable Hydraulic Fracturing (HF2013) which was held 20-22 May 2013 in Brisbane, Australia. The conference goal was to advance hydraulic fracturing technology that is effective in its purpose and sustainable in its impacts on communities and environments by bringing together hydraulic fracturing experts not only from the petroleum industry, but also from other application areas of hydraulic fracturing such as mining and geothermal energy production. Topics include hydraulic fracturing of naturally fractured formations, well completions and fracture initiation, induced seismicity, experimental investigations, and coupled modelling. Beyond this mix of traditional hydraulic fracturing research topics, this book includes papers on applications in mining and also on regulations, risk, and communities.
See on www.intechopen.com