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Offshore vessels / logistic

In two months, these will be out sailing on the ‘Acta Centaurus’

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In a little more than two months, the next offshore wind vessel for Acta Marine, the ‘Acta Centaurus’, will be completed and ready for CSV/SOV operation. Acta Marine’s site team is following the vessel’s progress on a daily basis, staying at Ulstein Verft on a 4-week schedule.

“The main topside equipment, including tower, gangway and crane, has been installed and tested previously, the helideck was the final equipment installation to take place,” says Marcus de Greef, who is Project Manager for Acta Marine. 

Next milestones approaching 

Marcus continues: “Commissioning of ships system such as main engines, propulsion system, bridge manoeuvring system together with completion of the interior in accommodation will be given focus the next weeks. Inclining test and yard sea trial are the largest remaining milestones”.

A social crew, appreciating the comfort and facilities on board

Several of the site team members will be working on board Acta Centaurus, and several have also been working on the sister vessel, Acta Auriga. From the stories they tell about daily life on board the vessel, we can tell that these crews and clients are highly sociable people, enjoying the on-board facilities after having served long shifts. One gaming room is not enough, so they’ve managed in good cooperation with Ulstein to fit in another gaming room on the Acta Centaurus. We’re not just talking about Nintendo or the likes, the crews also enjoy traditional board games, such as Chess and Risk. The gymnasium is actively used, as well as the sauna.

Cooperating closely with the yard

Michelle Lofflerwill be 1st officer On Acta Centaurus: ”I need to get familiarised with the vessel and the ship’s systems. My job, as well as the others in the team, is otherwise to secure that the shipbuilding contract is being followed up accordingly.“

 The yard is compact, and it is not hard to run into the supervisors when the site team needs to get hold of them.

“We have weekly meetings with the project management at the yard, and daily meetings with the yard supervisors,” Marcus explains.

Small town

The yard is small, and so is the town of Ulsteinvik, counting less than 6,000 inhabitants. The natural scenery is great, located at the Northwest coast of Norway where fjords are cutting the landscape, and with very short distance to the impressive alps of Sunnmøre and outdoor life. However, the choice of restaurants and nightlife is not in abundance. So, what do the teams do in their spare time?

“I’ve been a mariner for 32 years, and a captain for the late 25,” says Fons Martens, who will also be captain on the Acta Centaurus, adding: “I have been to yards for newbuild inspections in several parts of the world. As mariners, we are used to working 4-week shifts, so being here is no issue. We have long work hours. Here in Ulsteinvik, we mostly cook our own food, as the restaurant prices are much higher than in Holland, and we’re frequenting the local training centre.”

The Acta Auriga was built on speculation and received a two-year contract with OceanBreeze Energy before the vessel was delivered from Ulstein Verft. The Acta Centaurus is also built on speculation, as is the helideck. “More and more, the offshore wind activity is moving further offshore to remote location. More of the wind farms are now requesting a helideck, so we decided to have one installed to increase the flexibility of the vessel”, Marcus states.

Floating production, storage and offloading vessel

BW Ideol unveils its standard floating foundation for mass production with a disruptive market approach

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BW Ideol unveils its standard floating foundation for mass production with a disruptive market approach

During the FOWT event in Marseille, BW Ideol, one of the global leaders in the sector, unveiled its brand-new market approach combining standardization and mass production to a selected panel of utilities and partners.

With over 22 GW already awarded in Scotland, around 8 GW in the USA, and several GW currently being awarded or in the tendering phase elsewhere in the world, floating wind is now entering an industrialization phase.

With the aim of accompanying and driving this evolution, BW Ideol now offers a standardized floating foundation product – based on the Damping Pool® solution in operation since 2018 in France and Japan.

This universal floating foundation is optimized for all meteocean conditions prevailing on the main floating wind markets (with 3 product classes adapted to different environmental conditions) and compatible with all 15 MW+ wind turbines currently available. This product retains the competitive advantages of the Damping Pool® patent, particularly its compactness, with dimensions limited to 54 meters, and its shallow draft, below 12 meters in operation. It can be easily scalable to the next 20 MW+ wind turbines when available. This standard product, pre-certified in advance, unlocks mass-production by allowing multiple projects to be supplied from the same manufacturing line.

BW Ideol has also unveiled its manufacturing line blueprint, easily scalable and replicable on multiple port infrastructures, for the mass production of concrete floating foundations. This blueprint, optimizing each manufacturing steps, has a demonstrated capacity to produce up to one floating foundation per week, with minimal harbour requirements, guaranteeing local manufacturing and delivery time. It encompasses the structuration of the supply chain to ensure a lean manufacturing, its digitalization, quality control and a reduced carbon footprint.

Associated with the standard product, this manufacturing blueprint unleashes the volume effect to drive costs down across projects and provides developers with an early guarantee on price and delivery schedule. BW Ideol is the first floating foundation supplier to propose such an approach.

“The floating wind market is at a crossroads today: tens of gigawatts will need to be built in the coming years, requiring a change in paradigm from the floating foundation suppliers. We believe that adopting an approach similar to that of wind turbine manufacturers is necessary: offering a single and standard product, suitable for all geographies and turbines available on the market, produced in series based on manufacturing line serving multiple projects, so that developers can truly commit and know where they are heading” declared Paul de la Guérivière, Founder and CEO of BW Ideol.

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Offshore supply vessel

TotalEnergies launches a floating offshore wind pilot project to supply renewable electricity to an offshore oil & gas platform in the North Sea

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TotalEnergies launches a floating offshore wind pilot project to supply renewable electricity to an offshore oil & gas platform in the North Sea

TotalEnergies announces the launch of a pilot project consisting in a floating wind turbine to supply renewable power to Culzean offshore platform in the UK North Sea, thus pioneering an innovative decarbonization scheme.

The 3 MW floating wind turbine will be located 2 km west of the Culzean platform, 220 km off the eastern coast of Scotland. This turbine, expected to be fully operational by end 2025, will supply around 20% of Culzean’s power requirement, thereby reducing its GHG emissions. The turbine will be installed on a modular, light semi-submersible floater hull designed by Ocergy, allowing for fast assembly and optimized costs.

“This innovative pilot project aims at proving the concept of hybridization of power generation on an offshore facility, by integrating the generation of renewable electricity from a floating wind turbine with the existing power generation from gas turbines. It also aims at qualifying a promising floater design for the future of floating offshore wind”, said Marie-Noelle Semeria, Chief Technology Officer at TotalEnergies.

This pilot project was selected in Crown Estate Scotland’s Innovation and Targeted Oil & Gas (INTOG) leasing round, designed to encourage and support the use of offshore wind energy to directly supply offshore oil & gas platforms.

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Genel

All the Pretty Workhorses: Giant Wind Farm Comes to New Mexico, Featuring GE Vernova’s 3.6-154 Turbines

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Getting renewable electricity to big population centers is a growing challenge in the United States, but in the high desert of central New Mexico a plan is coming together. There, near the tiny town of Corona, GE Vernova will deploy 674 of its new “workhorse” 3.6-154 wind turbines* for the SunZia project and its developer, Pattern Energy. When completed in 2026, this colossus of a project will weigh in at a total 3,500 MW, making it the largest wind farm — and in fact the largest renewables project — in the Western Hemi- sphere, providing enough power for some 3 million people.

Spread out over a million acres, SunZia’s ambitious scope has been compared to the Hoover Dam. But it has a leg up on that landmark project: Back in the 1930s, the U.S. didn’t have access to the fast transmission technology available today. SunZia will send its wind-generated electricity through high-voltage direct current cable (HVDC) to Phoenix, where the power can be sent on ward to markets in Arizona and California. “This is just the kind of project,” says Steve Swift, chief commercial officer at GE Vernova’s Onshore Wind business, “needed to really decarbonize the U.S. and stay on the path to climate goals.”

To bring a project like this to fruition requires complex coordination. One of the biggest challenges in the burgeoning renewables space is the supply chain. Manufactured parts and materials like steel have to converge at the right points, at the right time, and must fit onto trains or ships. If you build your components so that they fit nicely with standard construction equipment, you’ll reach the finish line much faster. GE Vernova, which is providing 74% of the turbine capacity of Sun- Zia, has contracted to manufacture some of the turbine towers in Belen, New Mexico, near the project site, saving time and costs. (Facilities in Pueblo, Colorado, and Amarillo, Texas, will also manufacture towers.) The hubs that enable the turbine blades to spin, as well as the big rectangular box that holds the electronics, gears, and motor, known as the nacelle, will be manufactured by GE Vernova in Pensacola, Florida.

Putting it all together in a sparsely populated part of New Mexico is not easy, but the reduced complexity of the workhorse turbine makes the project and logistics execution much simpler. Not nearly as large as an offshore giant like GE Vernova’s 14-MW Haliade-X, the 3.6-154 turbine possesses what Kevin Siwik, director of North American sales at GE Vernova Onshore Wind, calls an efficient “logistics and construction envelope.”

This is a machine that can be delivered and installed at rapid scale compared with much larger machines, where you might trade logistics and construction efficiencies for larger nameplates — i.e., higher maximum outputs — “but won’t install at the same pace,” he says. “So this really is intended to be logistically friendly, in a quick time frame.” Siwik points out, for example, that the fleet of commercially available construction cranes in the region are the right fit for GE Vernova’s more compact workhorse, and wouldn’t be able to handle larger turbines. And as with any construction project, time is money: The faster the turbines are erected, the faster the return on investment.

Modeling the Landscape

SunZia is spread out over a million acres, on a rectangle of land roughly 80 by 30 miles, with GE’s turbine array covering a 45-by-25- mile portion of the whole. According to Matt Lynch, commercial director for North America at GE Vernova Onshore Wind, the site itself is challenging, because at that scale you have a lot of variance in topography. Computer modeling is used to find exactly the right spot for each of GE Vernova’s 674 turbines. “From the engineering perspective, having one single product fitting all those locations is a challenge,” says Soner Ozkan, senior account manager for Pattern Energy at GE Vernova Onshore Wind. Moreover, to send renewable electricity over the highlyefficient HVDC cable, which prevents the kind of line losses typical of older wires, the new wind power will have to be converted to direct current (DC) on-site before being converted back to alternating current (AC) in Phoenix.

That’s where another wing of GE Vernova steps in: Financial Services and Consulting Services. Regarding Consulting Services’ support, Ozkan says, “They have all the PhDs and the modeling capabilities. And we have weekly discussions with them.” While Hitachi Energy is handling the HVDC part of the construction project, Ozkan, Siwik, and Lynch stress that ongoing cooperation is needed to make sure all the technology works together.

GE Vernova’s services are integrated into the product development cycle, and for SunZia this meant providing customized software to the turbines, enabling them to work more efficiently with the long distance HVDC line. In a region known for lightning strikes, for example, turbines and the mini grid in which they’re nested are vulnerable to power spikes. But the system is designed to be able to respond to those surges within 50 milliseconds, ensuring that equipment is protected.

In addition, Financial Services assisted SunZia in reaching financial close with a sizable commitment to finance the monetization of future tax credits. In this way, GE Vernova offers a unique set of full-stack solutions, from modeling to financing, differentiating it from competitors that are unable to offer the same type of one-stop-shop approach.

Lynch says that sequencing a mega-project like SunZia is also crucial so that each completion goal is reached at the right time, in the right order: “What’s the best execution plan? What’s the best project cycle — not trying to make too aggressive a schedule, where neither party would succeed? What are the milestones? What’s the commercial operation date?”

Just one of the major tasks that needs to be addressed at a project like SunZia is establishing road access, a delicate operation required not only for building a pad for each turbine but for maintenance later on. The developer, Pattern Energy, has worked closely with the National Audubon Society to address the multiple environmental challenges involved in building such a big infrastructure project on healthy rangeland, as well as the impact of the route taken by its 550-mile transmission line across two states.

This is not the first time Pattern Energy and GE Vernova have danced together in the desert. The collaboration on SunZia grew out of the very successful 1,050-MW Western Spirit wind project, a nearby series of four clusters that is now operational after completion early last year. Western Spirit itself was a break- through. ”That was the largest single-phase installation to happen in the United States at one time, truly ushering in a new era of large- scale projects,” Siwik says. The workhorse turbine used in much of the Western Spirit project was a 2.7-MW machine with a rotor diameter of 127 meters (416 feet). Today’s workhorse, the 3.6-154 unit for SunZia, will have a rotor diameter of 154 meters (505 feet).

“Our outstanding performance in Western Spirit is really what led us here,” says Swift. “That project was built by the same parties — built on schedule, and on budget. Some call it one of the best executions through the pandemic they’ve ever seen.” By the time SunZia is completed, the Pattern Energy and GE Vernova teams will have together delivered a whopping 4.3 gigawatts of new renewable power across the western United States. Western Spirit has historically worked with other suppliers but is increasingly turning to GE as a favored project partner.

“SunZia is an investment in America’s energy future that will pay strong dividends, including more than $20 billion in expected economic impact, over 2,000 new jobs, and clean power for 3 million Americans,” says Hunter Armistead, CEO of Pattern Energy. “SunZia demonstrates that working toward a sustainable future can also create mean- ingful economic value and a lasting positive impact on local communities. We’re proud that SunZia is the result of many years of collaboration with communities, local residents, landowners, environmental groups, and government agencies. We look forward to bringing these benefits to fruition.”

Credits Where They’re Due

Recognizing that decarbonization needs to go even faster, the U.S. government has once again stepped up its policy support. For many years, solar and wind projects have benefited from the basic production and investment tax credits, which have been extended multiple times by Congress in the past. But the passage of the Inflation Reduction Act (IRA) not only provides the long-term certainty of those PTC and ITC, it also has other bonuses, and one job that GE Vernova takes on is helping developers hit the target required to qualify for those bonuses. Two in particular are in play in the SunZia project, according to Chrissy Borskey, GE Vernova’s executive director of global government affairs and policy.

First, the government identifies areas of the country that have seen job losses in mining and energy production, which makes them the perfect settings to award developer bonuses. While Borskey cautions that more clarification is needed from the U.S. Treasury and the Internal Revenue Service, much of New Mexicolies within this “energy community” designation. And there is no question that the SunZia project is expected to inject billions into the local economy and create more than 2,000 construction jobs during peak construction.

The second bonus comes through meeting the IRA’s U.S. manufacturing and sourcing rules. GE Vernova’s decision to produce nacelles and hubs in Florida while also delivering towers with U.S.made steel are aimed directly at meeting the targets required by the legislation. ”More projects similar to this can quickly move forward as the administration works diligently to finalize the rules and regulations related to the IRA,” Borskey says. While the details are still being worked out, GE Vernova is moving ahead and has invested $20 million in its Pensacola facility.

The U.S. has made great strides in decarbonizing its power grid in the past decade, shuttering coal plants and building so much new wind and solar that by the end of 2022 they accounted for nearly 15% of U.S. electricity, according to the Energy Information Administration. But to decarbonize effectively, the U.S. will need more projects of similar scale. SunZia’s size will more or less break the ceiling on large-scale projects, and should set an important precedent.

Pattern Energy and GE Vernova now seem to have optimized such projects to a fine- tuned science, or what Swift calls top-shelf “execution performance.” This bodes well for a future of further renewable energy deployment. Says Siwik, “I think that the message should come across as: If you have a large- scale single-phase project, you ought to be looking at GE Vernova technology.”

*GE’s 3.6-MW turbine with a 154-meter rotor is referred to as the 3.6-154 turbine.

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