The Anonymous Widower

Offshore Wind Turbines In 2025: China Continues Leading In Single-Unit Capacity, Vestas’s 15 MW Turbine Installed At Offshore Wind Farms

The title of this post, is the same as that of this article on offshoreWIND.biz.

This is the sub-heading.

In offshoreWIND.biz‘s 2024 annual wind turbine overview, you could have read about the first 16 MW floating wind platform installed offshore and a 26 MW prototype under construction, both in China, and a 21 MW prototype being assembled in Europe. Wind turbine generator (WTG) technology did not stop progressing in 2025, with Chinese OEMs still leading capacity-wise, while in Europe, first offshore wind farms are now featuring 15 MW turbines and a 21+ MW model was installed onshore for testing.

The article is very much a must-read and there is a lot of innovation going on.

As a comparison, between 2020 and 2026 we commissioned or are building these offshore wind farms in the UK.

  • East Anglia One – 2000 – 714 MW – 102 x 7 MW
  • Hornsea One – 2020 – 1218 MW – 174 x 7 MW
  • Kincardine – 2021 – 49.5 MW – 6 x floating
  • Hornsea Two – 2022 – 1386 MW – 165 x 8 MW
  • Moray East – 2022 – 950 MW – 100 x 9.5 MW
  • Triton Knoll – 2022 – 857 MW – 90 x 9.5 MW
  • Seagreen Phase 1 – 2023 – 1400 MW – 114 x 10 MW
  • Dogger Bank A – 2025 – 1235 MW – 95 x 13 MW
  • Moray West – 2025 – 882 MW – 60 x 14 MW
  • Neart Na Gaoithe – 2025 – 450 MW – 54 x 8 MW
  • Dogger Bank B – 2026 – 1235 MW – 95 x 13 MW
  • East Anglia 3 – 2026 – 1372 – 95 x 14 MW
  • Sofia – 2026 – 1400 MW – 100 x 14 MW

Average sizes for the various years are as follows.

  • 2020 – 7 MW
  • 2021 – floating
  • 2022 – 8-9.5 MW
  • 2023 – 10 MW
  • 2025 – 8-14 MW
  • 2026 – 13-14 MW

It can clearly be seen that in the last few years, turbines have been getting bigger.

I have some thoughts on the article.

2025 Saw Some Plans For And Installations Of Some Very Large Turbines

These four monsters were mentioned at the start of the article.

  • 26 MW – Prototype installed for testing (China)
  • 21.5 MW – Prototype installed for testing (Europe)
  • 15 MW Installed at offshore wind farms (Europe)
  • 50 MW Twin-turbine platform; Announced (China)
It would appear that much larger turbines are on the way.
This will not only mean some wind farms will be built with larger turbines, but also some older wind farms could be refitted with new larger turbines.
I Am Looking Forward To Seeing A Twin-Turbine Platform In Action
These posts talk about Swedish and Chinese designs.
Note.
  1. The Chinese seem to be providing turbines for both manufacturers.
  3. The TwinHub is the Swedish design, being built for trial in Cornwall.
  5. This new design is a 50 MW design, whereas these two are 32 MW.
It will be interesting to see how costs of single turbine designs compare with twin-turbine designs.

 

 

January 1, 2026 Posted by | Energy | , , , , , , , , , | 2 Comments

French Companies Unite On Superconducting Cable Project For Distant Offshore Wind Farms

The title of this post, is the same as that of this article on offshoreWIND.biz.

This is the sub-heading.

Air Liquide, CentraleSupélec, ITP Interpipe, Nexans, and RTE have joined forces to develop a project that connects distant offshore wind farms to shore via a High Voltage Alternating Current (HVAC) superconducting transmission system.

This introductory paragraph adds some detail.

The SupraMarine demonstrator project will study the electrical connection between offshore wind farms and the coastline using High-Temperature Superconducting (HTS) cables. Cooled by liquid nitrogen, the cables are said to transport electricity with near-zero energy loss.

Note.

  1. No details of the target distances are indicated.
  2. There is a detailed exploratory diagram.

It is certainly an ambitious project, but I feel it could have substantial uses.

I have a few thoughts and questions.

Can Sodium Metal Be Used For High Voltage Electrical Underground Cables?

Google AI answers this question as follows.

Yes, sodium metal was investigated and used in trial runs for high-voltage underground electrical cables in the late 1960s and early 1970s, as a potentially cheaper and more flexible alternative to copper and aluminum. However, it is not in common use today due to safety concerns and unfavorable lifecycle economics compared to aluminum.

When I was at ICI around 1970, they were researching the use of sodium for high voltage power cables.

  • ICI had access to large amount of sodium chloride in Cheshire.
  • The sodium metal can be obtained by electrolysis.
  • Renewable electricity for electrolysis will be plentiful.
  • Someone told me that their prototype cable was a polythene pipe with Sodium metal in the middle.
  • I’ve read somewhere that sodium cables have interesting safe overload properties.
  • I can understand the safety concerns and unfavorable lifecycle economics, especially where water is concerned.

Perhaps, French technology has improved in the sixty years?

Will Sodium Metal Be Used In The French Superconducting Cable?

Nothing has been disclosed!

But the office chat at ICI from those, who knew their sodium and their polythene, as they’d been working  at ICI Mond Division for decades, was of the opinion that sodium/polythene cables were possible!

From The Diagram, It Looks Like Power Is Needed At Both Ends Of The Superconducting Cable

The diagram shows wind turbines at one end and the grid at the other end of the cable.

So will a battery or some other form of stabilisation be needed for when the wind isn’t blowing?

Will The French Superconducting Cable Have A High Capacity?

The basic capacity of a cable depends on three properties.

  • The resistance of the cable.
  • The cross-section area of the cable.
  • The design of the cable must also be able too conduct away the heat generated by electricity flowing through.

Will The Technology Work For Interconnectors?

I don’t see why not!

 

December 13, 2025 Posted by | Energy | , , , , , | Leave a comment

DeepForm

On Wednesday I went to the TDAP Wave 8 Demo Day, which was organised by the Advanced Propulsion Centre.

One of the cohort of companies there was DeepForm, who were described like this.

DeepForm is transforming sheet metal pressing with its patented cold-shear press design, which reduces blank sizes by up to 45 % and trimming waste by up to 85%. This drop-in technology lowers material costs and embodied CO2 in existing press lines without compromising performance, quality or speed. Spun out of the University of Cambridge in 2022, DeepForm enables OEMs and Tier 1 suppliers to adopt the breakthrough through IP licensing, simulation and design support.

The company have an impressive web site, which deserves a very full read.

In their presentation, they showed two products, that could benefit from their innovation; a large steel component for Jaguar Land Rover and a humble aluminium drink can.

As I walked home ntoday, I saw this advert displayed on a bus stop.

The cans for BuzzBallz are also shown on the company’s web site.

But these products are are only the start.

For instance, I can see lots of small plastic items and components, that can’t be recycled, could be made from aluminium, which is easy to be recycle.

I also think companies like IKEA will love the design freedom, the technology will give.

November 27, 2025 Posted by | Business, Design, Food | , , , , , , , , , , , , | Leave a comment

UK Offshore Wind Farm Now Equipped With Scour Protection Doubling As Marine Life Habitat

The title of this post, is the same as that of this article on offshoreWIND.biz.

This is the sub-heading.

RWE has installed around 75,000 reef cubes developed by the nature-inclusive technology designer ARC marine at the Rampion offshore wind farm in the UK, in what the Rampion owner says is a “global first”. The cubes are a specially eco-engineered scour protection solution for wind turbine foundations, and this represents their first full-scale deployment at an offshore wind farm.

These four paragraphs add more details.

The solution is designed to protect the energy infrastructure from strong currents in the subsea environment, while creating new and extending existing living marine habitats, RWE says.

The reef cubes, ranging in size from 15 to 35 centimetres, were installed over the last few days at the base of one of the Rampion turbines by the project’s contractor Rohde Nielsen. It is the first real-world deployment of ARC marine’s patented Reef cubes as scour protection at an operational wind farm, according to RWE.

The developer says that at just one of the Rampion turbines, the reef cubes are providing a habitat surface area of 25,000 square metres.

The deployment is part of the Reef Enhancement for Scour Protection (RESP) pilot that RWE and ARC marine announced in July this year.

ARC marine’s reef cubes have their own comprehensive web site, which show all aspects of this fascinating technology.

 

 

October 16, 2025 Posted by | Energy | , , , , , , , | Leave a comment

Unlocking Efficiency With Cryogenic Cooling Of GaN Traction Inverters

The title of this post, is the same as this insight on the Ricardo web site.

This is the introduction.

As the mobility sector accelerates toward zero-carbon propulsion, hydrogen fuel cell systems (HFCS) are emerging as a cornerstone technology for aviation, marine, and long-haul road transport. Among the most promising innovations in this space is the use of liquid hydrogen (LH₂) not only as a fuel source but also as a cryogenic coolant for electric powertrains. This dual-purpose approach offers transformative potential in system efficiency, packaging, and weight reduction—especially when paired with Gallium Nitride (GaN) semiconductors.

It is a very simple concept, but it appears to give worthwhile efficiency gains.

This was the article’s conclusion.

Ricardo’s cryogenic GaN inverter concept represents a bold leap toward ultra-efficient, lightweight, and integrated hydrogen propulsion systems. While challenges remain in materials, packaging, and reliability, the experimental results are compelling. With efficiencies nearing 99.8% and mass reductions over 50%, cryogenic cooling could redefine the future of electric mobility.

As the hydrogen economy matures, innovations like this will be pivotal in delivering clean, scalable, and high-performance solutions across all mobility sectors.

I very much suggest, that you take the time to read the whole insight.

Using The Concept In a Liquid Hydrogen Carrier

This Wikipedia entry describes the design and operation of an ocean-going liquid hydrogen carrier.

This is a paragraph.

Similar to an LNG carrier the boil off gas can be used for propulsion of the ship.

Ricardo’s concept would appear to be advantageous in the design of liquid hydrogen carriers and I would expect, it could also be applied to the design of LNG carriers.

I would not be surprised to see liquid hydrogen and LNG carriers were the first application of Ricardo’s concept.

This Wikipedia entry describes the Suiso Frontier, which is the world’s only liquid hydrogen carrier.

I believe that Ricardo’s concept could lead to the construction of a more of these ships. Will they mean that liquid hydrogen carriers will deliver hydrogen from sunny climes to places like Europe, Japan, Korea and Canada.

The concept would also enable efficient small liquid hydrogen carriers, that could deliver hydrogen on routes like the North of Scotland to Germany.

Using The Concept In A Railway Locomotive

I could see freight locomotives being designed as a large liquid hydrogen tank with appropriately-sized fuel cells and added electrical gubbins.

  • They would be self-powered and would not require any electrification.
  • They would be much quieter than current diesels.
  • They could pull the heaviest freight trains, between Europe and Asia.
  • They could even pull passenger trains, if an electrical hotel supply were to be arranged.
  • They could be designed with very long ranges.

But above all they would be zero-carbon.

Note that I’ve written about long freight routes before.

I believe that a long-distance liquid-hydrogen locomotive, that was based on the Ricardo concept, would be ideal for some of these routes.

A Specialised Hydrogen Delivery Train

In April 2022, I wrote The TruckTrain, where this is a simple description of the concept.

The Basic Design Concept

The leaflet on their web site describes the concept.

This visualisation at the bottom of the leaflet shows four TruckTrains forming a train carrying twelve intermodal containers, each of which I suspect are 20 feet long.

I believe that the TruckTrain concept could be converted into a hydrogen delivery train.

  • It would be an appropriate length.
  • It would be powered by the on-board hydrogen.
  • The hydrogen would be stored as liquid hydrogen.

It would be able to go most places on the UK rail network.

Conclusion

Ricardo’s concept could revolutionise the use of hydrogen.

 

October 8, 2025 Posted by | Design, Hydrogen, Transport/Travel | , , , , , , , , , , | Leave a comment

South Eastern Railway Deploys IsoMat Thermal Technology To Keep Trains On The Tonbridge To Hastings Line Running In Hot Weather

The title of this post, is the same as that of this news item on the Network Rail web site.

This is the sub-heading.

A new type of technology is being trialled on the Tonbridge to Hastings railway line to help keep trains running in hotter weather, and more reliable journeys for passengers and freight customers.

These two paragraphs add more details.

The South Eastern Railway has partnered with UK green tech start-up Flint Engineering to combat excessive heat in railway signalling cabinets that can exceed 70°C, with a new patented system that requires no power, maintenance, or internal cabinet modifications, and can be installed in under an hour.

Flint’s innovative IsoMat technology delivers peak temperature reductions of over 21%, on the hottest days, transferring thermal energy thousands of times more efficiently than copper or aluminium alone.

This is one of those ideas, that could be filed under Too Good To Be True.

This picture shows the device in operation.

 

 

I can see this device having many uses, in the most surprising places.

 

August 26, 2025 Posted by | Energy, Transport/Travel | , , , , , | 2 Comments

Demonstration Of Commercial-Size Hydrogen Module

The title of this post, is the same as that of news item on the SunHydrogen web site.

This is the sub-heading.

SunHydrogen has successfully demonstrated live operation of its commercial-size 1.92m² hydrogen module, producing renewable hydrogen using only sunlight and water. This major milestone showcases the scalability and off-grid potential of the company’s renewable hydrogen production technology.

These first three paragraphs add more details.

SunHydrogen, developer of a breakthrough technology to produce renewable hydrogen using sunlight and water, today announced the successful live operation of its 1.92 m² (20.7 sq. ft.) hydrogen module. Conducted in an open prototype housing, the demonstration marks a pivotal milestone in the company’s path toward commercial-scale, renewable hydrogen production.

The 1.92m² hydrogen module, which uses only sunlight and water to produce hydrogen, represents the most advanced version of SunHydrogen’s proprietary hydrogen production technology. Engineered to operate independent of the electrical grid, the system integrates solar collection and hydrogen production into a single unit, offering a modular and scalable solution for distributed renewable hydrogen.

“This successful demonstration of the commercial-size reactor underscores the progress we’ve made in bringing our technology out of the lab and into the real world,” said Tim Young, CEO of SunHydrogen.

There is a video of this demonstration.

On their home page, there is a section called A Breakthrough In Clean Energy, where this is said.

SunHydrogen has developed a breakthrough technology to produce renewable hydrogen using sunlight and any source of water.

By optimizing the science of water electrolysis at the nano-level, our low-cost photoelectrochemical technology uses sunlight to separate hydrogen from water, making the process truly green from start to finish.

I will accept their word that it is truly green, but it is truly unique in that it doesn’t appear to use only sunlight to generate hydrogen.

 

August 13, 2025 Posted by | Energy, Hydrogen | , , | Leave a comment

Singapore’s First Hydrogen-Powered Data Center Launched By DayOne Using SOFC Technology

The title of this post, is the same as that of this article on Fuel Cell Works.

These two bullet points act as sub-headings.

  • DayOne has broken ground on its first AI-ready hyperscale data center in Singapore, a 20MW facility set to be operational in 2026. The project integrates 100% renewable energy, SOFC-based hydrogen power generation, and cutting-edge hybrid cooling technologies.
  • Strategic partnerships with Sembcorp and NUS will drive green energy adoption and R&D in sustainable tropical data center innovation, aligning with Singapore’s AI and digital infrastructure goals.

This data centre and the companies and the technologies behind it, are certainly ones to watch.

The R & D and innovation behind it could allow data centres to be built in more tropical places than is currently possible.

July 28, 2025 Posted by | Computing, Energy, Hydrogen | , , , , , , | Leave a comment

RWE Opens ‘Grimsby Hub’ For Offshore Wind Operations And Maintenance

The title of this post, is the same as that of this article on offshoreWIND.biz.

This is the sub-heading.

RWE officially opened its ‘Grimsby Hub’ offshore wind operations and maintenance (O&M) facility in the UK on 9 July. From the new O&M base, located at Associated British Ports’ (ABP) Port of Grimsby, RWE’s teams will maintain and operate the Triton Knoll and Sofia offshore wind farms.

These are the first two paragraphs.

The Grimsby Hub also houses RWE’s new UK Centralised Control Room (CCR), which has been set up to provide 24/7 monitoring of the company’s UK offshore wind farms and can provide services such as marine coordination, turbine operations, alarm management, high voltage monitoring and Emergency Response services with a team of twelve operatives, the developer says.

The O&M facility is already employing over 90 Full-Time Equivalents (FTEs), according to RWE, and is expected to employ around 140 RWE staff by 2027, as well as create approximately 60 new locally sourced jobs through the development of the CCR and ongoing offshore operations.

Note.

  1. Does RWE’s new UK Centralised Control Room control all their UK offshore wind farms?
  2. I have added them all up and there are almost 12 GW around our shores.
  3. I’ve read somewhere, that RWE are the UK’s largest power generator. From these figures, that would not surprise me.

This Google Map shows the location of RWE’s facilities in Grimsby.

Note.

  1. The bright red arrow at the top of the map indicates RWE Generation UK in Grimsby Docks.
  2. There is another RWE location to the right of the bright red arrow.
  3. There is a line of stations along the coast, which from left-to-right are Stallingborough, Healing, Great Coates, Grimsby Town, Grimsby Docks, New Clee and Cleethorpes.
  4. Cleethorpes is not shown on the map.
  5. Doncaster and Cleethorpes are 52.1 mile apart, which is within the range of a battery-electric Hitachi and other trains.
  6. Charging would be at Doncaster, which is fully electrified and at Cleethorpes, by a short length of electrification.

This OpenRailwayMap shows the layout of and the railways around Grimsby Dock.

Note.

  1. Cleethorpes station is indicated by the blue arrow, in the South-East corner of the map.
  2. Cleethorpes station has four platforms, but no electrification.
  3. Grimsby Docks are to the North of the railway to Cleethorpes.
  4. This Wikipedia entry for Cleethorpes station, shows other railways and light railways served the area. Some were even electric.

These are a few of my thoughts on the development of railways between Sheffield and Cleethorpes.

RWE Will Be A Large Driver Of Employment In Grimsby

Earlier I wrote.

  • Does RWE’s new UK Centralised Control Room control all their UK offshore wind farms?
  • I have added them all up and there are almost 12 GW around our shores.
  • I’ve read somewhere, that RWE are the UK’s largest power generator. From these figures, that would not surprise me.

It’s a long time, since I’ve added resources to a large project, so I asked Google AI, “How many people are needed to support a 1 GW offshore wind farm in the UK?”, and received this answer.

Based on data from large-scale UK offshore wind projects, a 1 GW (1,000 MW) offshore wind farm generally requires between 300 and 600+ people to operate and maintain, depending on whether the staff count includes direct operations, service vessel crews, and long-term supply chain partners. 
Operational Staffing: Ørsted’s 1.2 GW Hornsea 1 and 1.3 GW Hornsea 2 projects are supported by an East Coast Hub in Grimsby, which maintains a workforce of over 600 people.

Direct & Indirect Support: For a large-scale project, this often breaks down into approximately 100–150 direct, permanent, high-skilled roles (technicians, engineers, management) and hundreds more in indirect, contracted, or supply chain roles (vessel crews, port operations, logistics).

Industry Average: Studies suggest that for operations and maintenance (O&M), around 50–100 full-time equivalent (FTE) jobs are generated per GW of installed capacity in terms of direct, permanent staff.

Key Takeaways for a 1 GW Farm:

  • Direct Technicians/Operators: ~100–200+ (working on-site, turbines, or in control rooms).
  • O&M Support Services: ~300–400+ (vessel operators, port logistics, supply chain).
  • Total Operations Personnel: 300–600+ people. 

Google AI appeared to have borrowed the figure from Ørsted and Hornsea 1 and 2.

So if it’s correct, there will be a total of 7,200 personnel supporting RWE’s wind farms in the UK. Even if only a third were employed in Grimsby, that is still a lot of people to accommodate and who will need to travel to work.

I also think a lot of personnel will come in by train, as the station is close to RWE’s locations.

Will Grimsby Have An Aberdeen-Sized Office-Shortage Problem?

One of the biggest problems, I was always hearing in the 1970s, was the shortage of offices in Aberdeen for the use of the oilmen.

In RWE Goes For An Additional 10 GW Of Offshore Wind In UK Waters In 2030, I talked about RWE’s plans for the future and published this table of new wind farms.

  • Sofia – 1,400 MW
  • Norfolk Boreas – 1380 MW
  • Norfolk Vanguard East – 1380 MW
  • Norfolk Vanguard West – 1380 MW
  • Dogger Bank South – 3000 MW
  • Awel y Môr – 500 MW
  • Five Estuaries – 353 MW
  • North Falls – 504 MW

Note.

  1. Sofia is nearly complete.
  2. Only the three Norfolk and the Dogger Bank South wind farms  are on the East side of England and suitable to be serviced from Grimsby., but they still total 7,140 MW.

Has Grimsby got the office-space for all the people needed?

Could The Cleethorpes And Liverpool Lime Street Service Be Run By Battery-Electric Rolling Stock?

The various sections of this route are as follows.

  • Cleethorpes and Doncaster – No Electrification – 52.1 miles
  • Doncaster and Meadowhall – No Electrification – 15.2 miles
  • Meadowhall and Sheffield – No Electrification – 3.4 miles
  • Sheffield and Dore & Totley  – No Electrification – 4.2 miles
  • Dore & Totley and Hazel Grove – No Electrification – 29.2 miles
  • Hazel Grove and Stockport – Electrification – 3.3 miles
  • Stockport and Manchester Piccadilly – Electrification – 5.9 miles
  • Manchester Piccadilly and Deansgate – Electrification – 0.8 miles
  • Deansgate and Liverpool South Parkway -Not Electrified – 28.2 miles
  • Liverpool South Parkway and Liverpool Lime Street – Electrified – 5.7 miles

Adding the sections together gives.

  • Cleethorpes and Hazel Grove – No Electrification – 104.1 miles
  • Hazel Grove and Deansgate – Electrification – 10 miles
  • Deansgate and Liverpool South Parkway -Not Electrified – 28.2 miles
  • Liverpool South Parkway and Liverpool Lime Street – Electrified – 5.7 miles

Note.

  1. To cover the 104.1 miles to Hazel Grove battery-electric trains would probably need to leave Cleethorpes with full batteries.
  2. Doncaster is a fully-electrified station and passing trains may be able to have a quick top-up.
  3. In South Yorkshire Now Has Better North-South Connections, I calculated that Doncaster is a very busy station with 173 express trains per day calling at the station or one every 8.5 minutes.
  4. Will trains be able to stop for a long period to charge batteries?
  5. It may be prudent to electrify between Meadowhall and Sheffield, under the Midland Mainline Electrification.
  6. Sheffield and Dore & Totley is shown that it will be electrified, under the Midland Mainline Electrification.
  7. Do we really want to have electrification marching along the Hope Valley Line?
  8. I believe that hydrogen-hybrid locomotives will be a better solution for freight trains on scenic lines like the Hope Valley, as they are zero-carbon, powerful and with a range comparable to diesel.

I believe CAF, Hitachi and Siemens have off the shelf rolling stock and factories in this country, who could build trains for the Cleethorpes and Liverpool Lime Street route.

How Would You Charge Battery-Electric Trains At Cleethorpes?

This picture shows Cleethorpes station

Note.

  1. The four long platforms without  electrification.
  2. The platforms have recently been refurbished.
  3. The train in Platform 2 is a TransPennine Express Class 185 Siemens Desiro diesel train.

The simplest way to electrify the station would be to put up enough 25 KVAC overhead wires, so that battery-electric trains needing a charge could put up a pantograph and have a refreshing drink.

In Technology Behind Siemens Mobility’s British Battery Trains Hits The Tracks, I wrote about Siemens Rail Charging Converter.

This is a visualisation of a Siemens Rail Charging Converter in action.

Note.

  1. The track is electrified with standard 25 KVAC overhead electrification.
  2. The train is a standard Siemens electric or battery-electric train.
  3. Siemens Rail Charging Converter, which is the shed in the compound on the left is providing the electricity to energise the catenary.
  4. I suspect, it could power third rail electrification, if the Office of Rail and Road ever allowed it to be still installed.
  5. The Siemens Rail Charging Converter does have one piece of magic in the shed. I suspect it uses a battery or a large capacitor to help power the electrification, as it can be powered from any typical domestic grid supply.
  6. I also wonder, if it has safety devices that cut the power outside the shed if track workers or intruders are detected, where they shouldn’t be?
  7. It could even cut the power, when trains are not running to save power and increase safety.

This looks to me, that a Siemens Rail Charging Converter could be a superb example of out-of-the-box thinking.

Could The Cleethorpes And Barton-on-Humber Service Be Run By Battery-Electric Rolling Stock?

This OpenRailwayMap shows the railways of North-East Lincolnshire.

Note.

  1. Cleethorpes is in the South-East Corner of the map.
  2. Barton-on-Humber is in the North-West corner of the map and marked by a blue-arrow.
  3. Stations from South to North would be New Clee, Grimsby Docks, Grimsby Town, Great Coates, Healing, Stallingborough, Habrough, Ulceby, Thornton Abbey, Goxhill, New Holland and Barrow Haven.
  4. The line is double track.
  5. Cleethorpes and Barton-on-Humber is just 22.8 miles.
  6. A round trip would be under fifty miles, which would be well within range of a full-charge at one end.
  7. Service is one train per two hours (tp2h), which would only need a single train, shuttling between Cleethorpes and Barton-on-Humber.
  8. Two trains could provide an hourly service.

I would expect, that well-designed, solid and reliable German engineering could build a Siemens’ Rail Charging Connector that could charge four trains per hour (tph) at Cleethorpes station.

At present services are.

  • TransPennineExpress – 1 tph to Liverpool Lime Street.
  • East Midlands Railway – 1 tp2h to Barton-on-Humber
  • East Midlands Railway – 1 tp2h to Matlock via Lincoln and Nottingham
  • Northern Trains – 1 train per day (tpd) Sheffield via Brigg.

That is probably only about two tph.

Could The Cleethorpes And Sheffield Service Be Run By Battery-Electric Rolling Stock?

This is a description of the current Cleethorpes and Sheffield service.

  • It is run by Northern Trains.
  • The morning train leaves Sheffield at 09:54 and arrives in Cleethorpes at 11:40.
  • The afternoon train leaves Cleethorpes at 13:20 and arrives in Sheffield at 15:10.
  • The train is a Class 150 diesel train, which is a bit of a Joan Collins of a train – Of a certain age, but still scrubs up extremely well!
  • Intermediate stations are Worksop, Retford, Gainsborough Central, Kirton Lindsey, Brigg, Barnetby and Grimsby Town
  • The route length is 71.6 miles
  • Trains take about 45-50 minutes.

It is also a parliamentary train.

The Wikipedia entry for parliamentary train gives this description of the Cleethorpes and Sheffield service.

Via Kirton Lindsey & Brigg. Became a parliamentary service when weekday services were withdrawn in 1993. Regular trains have operated between Gainsborough and Sheffield for most timetable periods since. Suspended January 2022 by Northern, who cited COVID-19 and staffing issues , but the service was reinstated in December 2022. Changed in May 2023 to be one return journey on weekdays only.

In the 1950s and 1960s I lived in Felixstowe part of the time and in the 1970s and 1980s I lived near Woodbridge and I observed first hand the development of the Port of Felixstowe and the effects it had on the surrounding countryside.

The development of the Port of Felixstowe, has brought the following.

  • Improved roads and railways.
  • Ipswich is now an hour from London by train.
  • Ipswich is now a University town.
  • New housing and other developments, both in Ipswich and Felixstowe and the surrounding countryside.
  • Employment also has increased considerably, both in the Port and in surrounding towns.
  • Ipswich’s football team is very much respected all over Europe and has won the English top division, the FA Cup and the UEFA Cup.

When you consider the jobs that RWE could create in the Port of Grimsby, I believe that this could have similar effects in Grimsby and Cleethorpes, as the Port of Felixstowe had in East Suffolk.

Already, the following are being talked about.

  • A direct rail link between Cleethorpes and Grimsby to London.
  • Battery-electric trains between Cleethorpes and Grimsby and Doncaster, Manchester and Liverpool Lime Street.

I believe that an improved rail link between Cleethorpes and Sheffield could be the catalyst for much needed housing along the route, which would be to the benefit of Cleethorpres, Grimsby, Sheffield and all the intermediate towns and villages on the route.

and the affects this will have on the countryside around the town, I believe that a strong case can be made out for a more frequent service between Cleethorpes and Sheffield.

 

 

 

 

 

 

 

July 16, 2025 Posted by | Artificial Intelligence, Design, Energy, Sport, Transport/Travel | , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , | 2 Comments

National Grid Pioneers UK-First Trial Of 3D Printed Technology For Low-Carbon Substations

 

The title of this post, is the same as that of this press release from National Grid.

These three bullet points act as sub-headings.

  • Collaboration with Hyperion Robotics and the University of Sheffield will trial low-carbon 3D-printed concrete foundations including at National Grid’s Deeside Centre for Innovation in North Wales
  • Innovation could reduce waste, carbon emissions and costs to consumers of network construction
  • If rolled out across National Grid substations the technology could save up to 705 tons of concrete and 323 tons of CO2 and deliver £1.7 million in consumer savings versus traditional methods over a 10-year period

These two paragraphs give more details.

National Grid is working with Hyperion Robotics and the University of Sheffield on a UK-first trial to manufacture, install and test 3D-printed substation foundations, which have the potential to reduce construction-driven carbon emissions and reduce costs to consumers of network construction. This is part of National Grid’s commitment to leverage innovation to future-proof the network.

If the project is successful and the technology is rolled out across all National Grid substations, it is estimated it could save up to 705 tons of concrete and 323 tons of CO2 over a 10-year period, and deliver £1.7 million in consumer savings versus traditional methods.

The foundation design will deliver significant savings across the entire value chain.

  • 70% reduction in concrete usage
  • 80% less soil displacement
  • 65% decrease in embodied carbon emissions
  • 70% weight reduction compared to typical foundations
  • 50% reduction in site operative hours, streamlining production

The foundations will be designed and produced in Finland by Hyperion Robotics, and tested at full-scale by the University of Sheffield. Further field testing will then be carried out at National Grid’s state-of-the-art testing facility, the Deeside Centre for Innovation in North Wales, later in 2025.

Conclusion

I like this technology and I suspect there are many other applications of 3D Concrete Printing.

 

 

June 23, 2025 Posted by | Design, Energy | , , , , , , , , | 1 Comment

« Previous Entries