Funding Announced For First-In-Class Low-Carbon Installation Vessel For Floating Offshore Wind
The title of this post, is the same as that of this news item from Morek Engineering.
These two paragraphs outline the project.
The UK Government has awarded funding to a consortium led by Morek Engineering to design a new class of low-carbon installation vessel for the floating offshore wind market.
The consortium has won the funding through the UK Government’s Clean Maritime Demonstration Competition based on their proven track record in innovative vessel design and delivery of complex offshore operations. The consortium includes Morek Engineering, Solis Marine Engineering, Tope Ocean, First Marine Solutions and Celtic Sea Power.
Note.
- The design of the ship certainly seems to tick all the boxes.
- This is Morek’s web site.
Because of my experience of writing project management systems, I often wonder, whether some of my discarded ideas of the 1980s could be used in the deployment of floating offshore wind.
South Korean Team To Develop SMR-Powered Ships
The title of this post is the same as that of this article on Neutron Bytes.
This is the introductory paragraph.
Nine South Korean organizations have signed a memorandum of understanding (MoU) to cooperate on the development and demonstration of ships and offshore systems powered with small modular reactors (SMRs). The partners will also develop marine systems and the production of hydrogen using molten salt reactors (MSRs).
These points are listed about nuclear-powered ships.
- Over 160 ships are powered by more than 200 small nuclear reactors.
- Most are submarines, but they range from icebreakers to aircraft carriers.
- In future, constraints on fossil fuel use in transport may bring marine nuclear propulsion into more widespread use.
- So far, exaggerated fears about safety have caused political restrictions on port access.
Note.
- When as a child, I used to watch the large container ships at Felixstowe, I thought then, that they could be nuclear-powered.
- One engineering lecturer at Liverpool University in the 1960s, was talking about nuclear-powered tunneling machines.
- Rolls-Royce to name just one company must have the reactor technology.
I just wonder, when the Korean President and his wife visited the UK, just before Christmas, that nuclear-powered ships were discussed.
Mortenson Announces Completion Of Edwards & Sanborn Solar + Storage Project
The title of this post, is the same as that of this press release from Mortenson.
These two paragraphs describe the project,
Terra-Gen and Mortenson have announced the full substantial completion of the Edwards & Sanborn Solar + Energy Storage project, the largest solar plus energy storage project in the United States. Mortenson was the full Engineering, Procurement, and Construction (EPC) contractor on both the solar and energy storage scopes for this vanguard project in the energy industry.
This project stretches over 4,600 acres and includes more than 1.9 million First Solar modules. In total, the project generates 875 MWdc of solar energy and has 3,287 megawatt-hours of energy storage with a total interconnection capacity of 1,300 megawatts. The project supplies power to the city of San Jose, Southern California Edison, Pacific Gas & Electric Co. and the Clean Power Alliance, and Starbucks, among others. A portion of the project is situated on the Edwards Air Force Base and was the largest public-private collaboration in U.S. Department of Defense history. The project uses LG Chem, Samsung, and BYD batteries.
Note.
- 4,600 acres is just over seven square miles.
- There’s more about this massive project on this web page.
- Judging by the fact, they use three different makes of batteries, did Mortenson have a problem sourcing the number needed from a single manufacturer or are the contractors seeing, which perform best in the hot desert?
California and other places can build these projects, if there is masses of sun and flat desert.
Shotwick Solar Park is the largest solar farm in the UK. It has a capacity of 72.2 MW.
Poo power To Heat Homes In West London As Thames Water Continues To Reduce Its Carbon Footprint
The title of this post, is the same as that of this press release from Thames Water.
These are the three bullet points.
- Thames Water unveils its second successful gas-to-grid project.
- Around 4000 homes in West London will be heated using converted sewage sludge from Mogden sewage treatment works starting early this year.
- This initiative is part of Thames Water’s commitment to reduce its carbon emissions across its operations thereby reducing its contribution to the causes of climate change.
These three paragraphs outline the project.
Thames Water has announced sewage sludge will be used to heat homes in West London early this year, after successfully delivering its second gas-to-grid (G2G) project, at its Mogden Sewage Treatment Works (STW).
The success of the gas-to-grid model established at Deephams STW in North London in 2021, where biogas is converted into biomethane to heat homes in Enfield, served as the blueprint for the project at Mogden.
Currently serving over 2 million customers, Mogden is the third largest STW in the UK, and has the potential to reach and supply gas to 4000 homes in West London. This comes as part of the company’s commitment on energy transition, by transforming the way it creates and uses power to reach net zero carbon emissions.
The press release then gives a paragraph of explanation as to how the system works.
A byproduct of the sewage treatment process is sewage sludge, which is then digested to produce BioGas. Mogden STW then generates electricity with this BioGas via Combined Heat and Power (CHP) engines. The Gas-to-Grid plant, which will be managed by gas supplier SGN, intends to take a proportion of this BioGas and to ‘uprate’ it to export quality which is achieved by filtering, scrubbing and then compressing gas so it can be used as fuel for cooking and heating.
This Thames Water graphic illustrates the process.
This press release is not Thames Water’s image from many of its customers.
RWE And National Grid Answer New York Offshore Wind Call
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
Community Offshore Wind, a joint venture of RWE and National Grid Ventures, has submitted a proposal to the New York State Energy Research and Development Authority (NYSERDA) to develop 1.3 GW of new offshore wind capacity in response to New York’s expedited fourth competitive offshore wind solicitation.
These four paragraphs add more details.
This next phase of the project builds upon Community Offshore Wind’s provisional offtake award to deliver 1.3 GW of wind capacity as part of New York’s third solicitation for offshore wind. In total, the projects are expected to generate USD 4.4 billion in economic benefits to New York.
Combined with its provisionally awarded New York project, Community Offshore Wind is on track to deliver nearly USD 100 million in workforce and economic development investments, the developer said.
The new proposal includes nearly USD 50 million in funding for workforce and community initiatives, with a focus on creating opportunities for diverse New Yorkers and supporting local non-profit organizations.
The proposal also includes an investment of up to USD 10 million in the offshore wind supply chain, to help New York businesses prepare for the economic opportunities the growing industry will create. All of these commitments are contingent on NYSERDA’s final selections.
is this partly a result of the meeting between Energy Security Secretary Claire Coutinho and Germany’s Vice Chancellor, Robert Habeck, that I wrote abut in UK And Germany Boost Offshore Renewables Ties?
We certainly seem to be getting some good deals on renewable energy these days with the Germans and the Koreans.
Perhaps someone in the government is doing something right?
British Gas Joins Forces With Samsung To Help Customers Power Smarter Energy Use
The title of this post, is the same as that of this press release from Centrica.
This is the sub-heading.
British Gas and Samsung have today announced the exciting first step in a long-term venture – aimed at helping customers better manage their energy use and increase the adoption of low carbon heating technologies in homes across Britain.
These are the first two paragraphs.
The collaboration will see British Gas integrate with Samsung’s SmartThings app to help customers optimise their home appliances to use energy when the cost and demand are lower. This is now possible through the integration of SmartThings Energy and British Gas’ PeakSave demand flexibility scheme informing customers (by sending notifications via their smartphone, TV or other compatible devices) of the best times to use household appliances to save money.
The PeakSave scheme includes PeakSave Sundays, running every Sunday until the end of February with half-price electricity from 11am to 4pm for British Gas customers and PeakSave Winter events which encourages customers to move their electricity use out of peak times when there is high demand on Britain’s energy grid.
As a Graduate Control Engineer, I believe that this could make optimising your energy use much easier.
- It would surely be a lot easier to check usage on your phone rather than a smart meter, when you perhaps cook a ready meal, so that you can see if your microwave or traditional cooker is cheapest.
- Suppose you and everybody, who lives with you are out for supper and British Gas want to cut off your gas for a reward, you can make an appropriate decision.
- Hopefully, if you have the right controls, you’ll be able to switch lights and appliances off and on.
The possibilities are endless.
I shall certainly be looking at the reviews of this app.
There is a section in the press release called Scaling Up Low Carbon Heating Opportunities, where this is said.
The collaboration will also help support customers in their journey to decarbonising their homes by introducing smart technologies in a way that is simple and empowering. From early 2024, British Gas will include Samsung heat pumps in its offering to British households to support the UK’s commitment to reach net zero by 2050.
The venture will see specially trained British Gas surveyors and engineers working with consumers to explain the benefits of heat pumps and then conducting the installations on-site. Samsung will be supporting workforce training as part of their efforts to upskill the heating industry to ensure there are enough installers to service the expected growing demand.
British Gas also offers customers the chance to purchase heat pumps through flexible financing methods. This, combined with the recently increased UK Government Boiler Upgrade Scheme grant of £7,500, creates an attractive package of financing options to help people make the transition more affordable.
Various plumbers, who I would trust, have given me different views about heat pumps.
I suspect the Samsung’s SmartThings app might be able to simulate your energy usage with or without the heat pump, as it would know your energy use with your current boiler.
I was doing similar calculations for chemical plants in the early 1970s at ICI, using a PACE 231-R computer.
Consider.
- It may look rather old fashioned, but it could solve a hundred simultaneous differential equations in one go.
- Two similar computers linked together were the analogue half of NASA’s moon mission simulator.
- Without these wonderful machines, NASA would not have been able to re-calculate the dynamics of Apollo 13 and the mission would be remembered as a disaster, rather than the first space rescue.
The average current smart phone has more computing power than a PACE 231-R.
What’s In It For Samsung?
I have a Samsung television, but unfortunately it has a screen fault because of age. So if I had the Samsung app and liked it, I might buy another Samsung TV.
Similarly, the app might give me a financial reason to buy a Samsung heat pump.
Samsung will sell more equipment.
What’s In It For Centrica?
Centrica would appear to be a loser, as bills will fall and they could be paying customers to not use energy.
But they are surely hoping that their market share will increase and I’m sure Samsung will give them a commission.
What’s In It For The Consumer?
Hopefully, they’ll get lower energy bills.
But also they might get a lot of convenience controlling their appliances and heating.
Conclusion
Using energy is becoming a computer game with monetary rewards.
Is the deal between Centrica/British Gas and Samsung another deal that has been brought to fruition by the Korean President’s visit to the UK?
It looks like this is the third recent deal signed between UK and Korean companies, after these two.
- South Korea, UK Strenghten Offshore Wind Ties
- UK And South Korea Help Secure Millions For World’s Largest Monopile Factory
I suspect, there might be a few more deals, if Charles and Camilla really turned on the charm.
In Mersey Tidal Project And Where It Is Up To Now, I wrote about talks between Liverpool City Council and Korea Water about a tidal barrage of the Mersey. This project must surely be a possibility!
This is said in the Wikipedia entry for Korean Air under Fleet Plans.
At the Association of Asia Pacific Airlines Assembly in 2018, Korean Air announced that it was considering a new large widebody aircraft order to replace older Airbus A330, Boeing 747-400, Boeing 777-200ER and Boeing 777-300. Types under consideration for replacement of older widebody aircraft in the fleet include the Boeing 777X and Airbus A350 XWB. At the International Air Transport Association Annual General Meeting (IATA AGM) in Seoul, Chairman Walter Cho said Korean Air’s widebody order is imminent and it is considering an extra order of Airbus A220 Family including developing version, Airbus A220-500.
Note.
- Airbus A350 XWB have Welsh wings and Rolls-Royce engines.
- Airbus A220-500 are made in Canada with wings and composite parts from Belfast. Rolls-Royce may have a suitable engine.
Could a deal have something in it for the UK?
Although Korea has its own SMR program, I wonder, if there could be a link-up between Korean industry and Rolls-Royce over SMRs?
BESS Projects Represent ‘Encouraging Progress’ in New York Efforts To Replace Dirty And Polluting Peakers
The title of this post, is the same as that of this article on Energy Storage News.
These are the first three paragraphs.
Battery storage is playing an active role in helping New York City retire its fleet of peaker power plants, with around 700MW of its most polluting power generation assets already fully retired.
According to a new report, 4,019MW – about two-thirds of a 6,093MW fleet – has either retired or put in place plans to replace turbines with cleaner technologies since New York adopted its climate goals and environment protection policies in 2019.
In addition to 700MW already retired, around the same amount again is actively being moved towards end of life.
Note.
- Just over 6,000 MW seems a lot of extra peaker power, even for a city as large as New York.
- But at least over 4 GW has been retired or the plans to replace it with cleaner technologies are in place.
- The New Yorkers certainly seem to be getting on with the conversion, with about a GW/per year either retired or planned to do so.
The article says this about batteries.
Battery storage is one of a number of different technologies that can be used to replace peaking capacity. While lithium-ion batteries with 4-hour duration might be the most directly analogous in terms of technical capability to peakers, effectively retiring the power plants could be facilitated with a combination of other resources including rooftop solar, offshore wind and energy efficiency measures.
I find the 4-hour duration interesting, but I suspect the Yanks know what they’re doing.
So if you were going to replace the 240 MW Glanford Brigg power station, which Centrica describe as a peaker station, with energy storage, you’d use a 240 MW/960 MWh battery, if you were working to New York rules.
Batteries in the UK, that I’ve talked about lately include.
Amp Hunterston – 400 MW/800 MWh – 2 hours
Amp Kincardine – 400 MW/800 MWh – 2 hours
- Carlton Energy Park – 1040 MW/2080 MWh – 2 hours – Close to an 884 MW gas-fired power station.
- Coalburn – 500 MW/1000 MWh – 2 hours- Close to a 946 MW collection of wind farms.
- Gateway Energy Centre – 450 MW/900 MWh – 2 hours – Close to an 732 MW gas-fired power station.
- Normanton Energy Reserve – 500 MW/1000 MWh – 2 hours
- Richborough Energy Park – 100 MW/100 MWh – 1 hour
- Spalding Energy Centre – 550 MW/1100 MWh – 2 hours – Close to an 860 MW gas-fired power station.
Note.
- The first field is Output/Storage Capacity.
- The second field is the duration.
- I have assumed Spalding Energy Centre is another two hour duration system, like Gateway Energy Centre, which is also being developed by Intergen.
- Two hours seems to be the most common duration for a UK battery.
Adding the batteries up gives a virtual 3940MW/7780MWh battery.
It amazing how they add up to quite large values. But then every little helps!
And these are only the ones I’ve talked about.
H2 Green Steel Raises More Than €4 billion In Debt Financing For The World’s First Large-Scale Green Steel Plant
The title of this post, is the same as that of this press release from H2 Green Steel.
This is the sub-heading.
H2 Green Steel signs definitive debt financing agreements for €4.2 billion in project financing and increases the previously announced equity raised by €300 million. Total equity funding to date amounts to €2.1 billion. The company has also been awarded a €250 million grant from the EU Innovation Fund. H2 Green Steel has now secured funding of close to €6.5 billion for the world’s first large-scale green steel plant in Northern Sweden.
These three paragraphs describe the company and outlines the financing.
H2 Green Steel is driving one of the largest climate impact initiatives globally. The company was founded in 2020 with the purpose to decarbonize hard-to-abate industries, starting by producing steel with up to 95% lower CO2 emissions than steel made with coke-fired blast furnaces. The construction of the flagship green steel plant in Boden, with integrated green hydrogen and green iron production, is well under way. The supply contracts for the hydrogen-, iron- and steel equipment are in place. A large portion of the electricity needed has been secured in long-term power purchase agreements, and half of the initial yearly volumes of 2.5 million tonnes of near zero steel have been sold in binding five- to seven-year customer agreements.
Today H2 Green Steel announces a massive milestone on its journey to accelerate the decarbonization of the steel industry, which is still one of the world’s dirtiest. The company has signed debt financing of €4.2 billion, added equity of close to €300 million and been awarded a €250 million grant from the Innovation Fund. Funding amounts to €6.5 billion in total.
H2 Green Steel has signed definitive financing documentation for €3.5 billion in senior debt and an up-to-€600 million junior debt facility:
Note.
- I first wrote about H2 Green Steel about three years ago in Green Hydrogen To Power First Zero Carbon Steel Plant.
- The Wikipedia entry for Boden in Northern Sweden, indicates it’s a coldish place to live.
- In that original post, H2 Green Steel said they needed €2.5 billion of investment, but now they’ve raised €4 billion, which is a 60 % increase in financing costs in just three years.
Is this Sweden’s HS2?
The Future Of Green Steelmaking
The finances of H2 Green Steel look distinctly marginal.
I have a feeling that green steel, as the technology now stands is an impossible dream.
But I do believe that perhaps in five or ten years, that an affordable zero carbon method of steel production will be developed.
You have to remember, Pilkington developed float glass in the 1950s and completely changed an industry. Today, we’d call that a classic example of disruptive innovation.
The same opportunity exists in steelmaking. And the rewards would be counted in billions.
SeAH Wind Goes On Recruitment Spree For UK Monopile Factory
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
South Korea’s SeAH Wind has started its large-scale drive to recruit for positions including welders, platers, roll bending machine operatives, mechanical and electrical technicians, supervisors, and general operatives for its XXL monopile manufacturing facility on Teesworks, the UK.
These are the first two paragraphs.
Applications will be accepted via the company’s dedicated recruitment website where individuals can sign up for job alerts, register their expressions of interest, and apply directly for jobs.
SeAH Wind will hold events across multiple Teesside towns, including Middlesbrough, Redcar, Cleveland, and Hartlepool over the coming months where more details will be shared about vacancies and training opportunities at the South Bank site.
These three paragraphs talk about the education and training, and the number of jobs.
As part of the recruitment drive, the South Korean firm has also joined forces with Nordic Products and Services and Middlesbrough College to create two programmes under its SeAH Wind Academy programme.
During the 24-week training and development programme, 30 people will be trained to become welders for SeAH Wind.
Once fully operational, it is expected that a total of 750 direct jobs and 1,500 further supply chain jobs are set to come from the SeAH manufacturing facility.
I suspect, this the sort of investment that Teesside needs and will welcome.
Europe Installs Record-Breaking 4.2 GW Of Offshore Wind In 2023
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
Europe’s offshore wind industry brought online a record 4.2 GW of new capacity in 2023 and is expected to build around 5 GW of offshore wind annually over the next three years, according to WindEurope data. However, this is still not enough to meet the continent’s 2030 climate and energy security targets, WindEurope added.
These are the first two paragraphs.
The overall offshore wind capacity installed in 2023 was 40 per cent higher than in 2022. Of the 4.2 GW of new capacity, 3 GW was in the EU, an increase of 2.1 GW year on year, WindEurope said.
The Netherlands, France, and the UK installed the most new capacity, including the 1.5 GW Hollandse Kust Zuid offshore wind project in the Netherlands, according to the organisation.
But where are the Germans?
They’ve got plenty of steel and sea, Siemens make a lot of wind turbines and they certainly need the electricity.
In 2023, Germany generated their electricity as follows.
- Brown coal (17.7%)
- Hard coal (8.3%)
- Natural gas (10.5%)
- Wind (32.0%)
- Solar (12.2%)
- Biomass (9.7%)
- Nuclear (1.5%)
- Hydro (4.5%)
- Oil (0.7%)
- Other (2.9%)
By comparison the UK’s figures were.
- Coal (1%)
- Natural gas (32%)
- Wind (29.4%)
- Solar (4.9%)
- Biomass (5%)
- Nuclear (14.2%)
- Hydro (1.8%)
- Storage (1%)
- Imports (10.7%)
Note.
- The Germans use a lot of coal.
- The UK uses a lot more natural gas.
- Despite the much-criticised Drax, the Germans use twice as much biomass as we do.
- The UK uses tens times more nuclear.
The Wikipedia entries for German and UK wind power make interesting reading.
The Anonymous Widower 