DeepCwind Consortium


The DeepCwind Consortium is a national consortium of universities, nonprofits, utilities, and industry leaders. The mission of the consortium is to establish the State of Maine as a national leader in floating offshore wind technology. Much of the consortium's work and resulting research has been funded by the U.S. Department of Energy, the National Science Foundations, and others.
The efforts of the DeepCwind Consortium culminated in the University of Maine patent-pending VolturnUS, a floating concrete hull technology can support wind turbines in water depths of 45 meters or more, and has the potential to significantly reduce the cost of offshore wind.

Overview

The DeepCwind Consortium was initially funded in 2009 as part of the American Recovery and Reinvestment Act through the U.S. Department of Energy. The University of Maine received $7.1 million to found the consortium and design and deploy floating offshore turbine prototypes. As part of this funding, the research plan included: "optimization of designs for floating platforms by evaluating options for using more durable, lighter, hybrid composite materials, manufacturability, and deployment logistics."
Floating deepwater wind farms placed ten or more nautical miles offshore can play a critical role in reaching the Department of Energy's 20% windpower goal by 2030. Deepwater offshore wind is the dominant U.S. ocean energy resource, representing a potential of nearly 3,100 TW-h/year. It also:
With these qualities in mind, Maine plans to construct a 5 GW, $20 billion network of floating offshore wind farms to contribute to the northeast U.S. renewable energy needs. Maine has the deepest waters near its shores, approximately 200 ft deep at 3 nmi, and 89% of Maine's 156 GW offshore wind resource is in deep waters. The state also offers extensive maritime industry infrastructure and proximity to one of the largest energy markets in the country.

Research Outcomes

The DeepCwind Consortium published the Maine Offshore Wind Report in February 2011. The report "examines economics and policy, electrical grid integration, wind and wave, bathymetric, soil, and environmental research. It also includes summaries of assembly and construction sites, critical issues for project development and permitting, and an analysis of the implications of the Jones Act."
In June 2013, the consortium deployed the 20 kW VolturnUS 1:8, a 65-foot-tall floating turbine prototype that is 1:8th the scale of a 6-megawatt, 450-foot rotor diameter design. VolturnUS 1:8 was the first grid-connected offshore wind turbine in the Americas.
In June 2016, the UMaine-led New England Aqua Ventus I project has just won top tier status from the US Department of Energy Advanced Technology Demonstration Program for Offshore Wind. New England Aqua Ventus I is a two 6 MW turbine floating offshore wind pilot project 14 miles off Maine's coast, developed by Maine Aqua Ventus, GP, LLC. The objective of the pilot is to demonstrate the technology at full scale, allowing floating farms to be built out-of-sight across the US and the world in the 2020s, bringing lower-cost, clean renewable energy to coastal population centers.

Partnering Organizations and Original Research Initiatives

The University of Maine-led consortium includes universities, nonprofits, and utilities; a wide range of industry leaders in offshore design, offshore construction, and marine structures manufacturing; firms with expertise in wind project siting, environmental analysis, environmental law, composites materials to assist in corrosion-resistant material design and selection, and energy investment; and industry organizations to assist with education and tech transfer activities.

Task 1: Micrositing, Geophysical Investigations, and Geotechnical Engineering

The primary objective of micrositing, geophysical investigations, and geotechnical engineering was the characterization of the seafloor environment for turbine anchoring at the University of Maine Deepwater Offshore Wind Test Site in the Gulf of Maine. Activities coordinated geologic and geotechnical engineering information with the metocean forces assessed in the Offshore Turbine Testing, Monitoring, and Reliability task and assisted in design of efficient moorings and anchors for the floating offshore wind turbines under the Floating Turbines Design and Lab Testing task. An additional objective of this task was to provide site location documentation and address safety and navigation at the site once the turbines and moorings are installed.
Partners: University of Maine Department of Civil and Environmental Engineering, James W. Sewall Company, Maine Maritime Academy, University of Western Australia Centre for Offshore Foundation Research

Task 2: Study of Environmental/Ecological Impacts

Maine Public Law 270, which allowed the establishment of the University of Maine Deepwater Offshore Wind Test Site, required that the following state and federal agencies be consulted concerning environmental monitoring and planning of the test site:
These agencies required plans for siting, navigation, project removal, remedial action, and environmental/ecological monitoring. They also required reports and updates on site activities.
There were to be wildlife-specific studies for:
As part of the environmental/ecological monitoring plan that was part of the test site permit application, a review of the potential threats to marine life was considered and mitigation measures were designed. Potential areas of concern addressed in this report included the following:
All micrositing, environmental/ecological monitoring, and permitting activities were conducted from the start of the project in 2010 until the end of the project in 2012.
Partners: University of Maine School of Marine Sciences, University of Maine School of Biology and Ecology, Island Institute, Gulf of Maine Research Institute, New Jersey Audubon Society, Pacific Northwest National Laboratory

Task 3: Permitting and Policy

Under the recently enacted Maine Public Law 2009, Chapter 270, the University of Maine Deepwater Offshore Wind Test Site is located near Monhegan Island, an area selected by the state. This site was analyzed in detail through the state's site selection process.
With Maine's designation of the test site, the Permitting and Policy team secured specific permits for the proposed project from all applicable local, state, and federal permitting authorities. In conformance with the application requirements, to obtain a General Permit under LD 1465, the Permitting and Policy team, in conjunction with the Micrositing and Ecological Monitoring teams, submitted a report to the required state and federal agencies describing:
The team worked to develop these plans in consultation with federal, state, and local agencies, as well as stakeholders.
Partners: James W. Sewall Company, Kleinschmidt, HDR/DTA

Task 4: Floating Turbine Design, Material Selection, and Lab Testing

The primary objectives of the Floating Turbine Design task was to:
Partners: Advanced Structures and Composites Center, Maine Maritime Academy, Technip USA, National Renewable Energy Laboratory, Sandia National Labs, Ashland, Inc., Kenway Corporation, Harbor Technologies, PPG Industries, Owens Corning, Zoltek, Polystrand, Inc.

Task 5: Offshore Turbine Testing, Monitoring, and Reliability

The Physical Oceanography Group at the University of Maine deployed and operated an oceanographic data buoy with real-time telemetry capabilities in the University of Maine Deepwater Offshore Wind Test Site offshore Monhegan Island. The ocean data buoy was deployed prior to the tank testing and remained in operation throughout the project period in order to monitor oceanographic, meteorological, and general environmental conditions. Monitoring emphasis was on wind speed and direction, visibility, directional waves, and water-column currents.
Partners: University of Maine Physical Oceanography Group, University of Maine School of Marine Sciences

Task 6: Education and Outreach

The University of Maine, Maine Maritime Academy, and Northern Maine Community College developed several degree programs to create a trained workforce for the State of Maine. To ensure the community at large understands our research and development, the DeepCwind Consortium found numerous opportunities to share and discuss goals, activity plans, and the results of research. The consortium held public meetings to discuss the site selection for the University of Maine Deepwater Offshore Wind Test Site, presented at conferences within the state and across the country, and even taught an interactive wind-wave tank testing activity to over 500 K-12 students across Maine. These and other activities continued through the duration of the project.
Partners: Advanced Structures and Composites Center, University of Maine College of Engineering,
University of Maine Department of Industrial Cooperation, Maine Maritime Academy, Northern Maine Community College, American Composites Manufacturers Association, Maine Composites Alliance, Maine Wind Industry Initiative
Task 8: Fabrication and Deployment
UMaine and its subcontractors led the fabrication and deployment of the approximately 1/8 scale floating wind turbine platform. The deployment study sought to identify key deployment and installation factors. The performance data gathered from the 1/8 scale platform was used to further validate platform numerical models developed by NREL and others.
Partners: Advanced Structures and Composites Center, Cianbro Corporation, General Dynamics Bath Iron Works, Maine Maritime Academy, Emera Maine, Central Maine Power Company, Technip USA, Reed and Reed, SGC