No Panic At The Pumps … South Koreans Just Stop Driving On Wednesdays
The title of this post, is the same as that of this article on The Times.
This is the sub-heading.
President Lee Jae-myung has urged the public to ‘save every drop of fuel’ and introduced a number-plate rotation to keep drivers off the road
These first three paragraphs deeply illustrate the differences between the energy situation in North and South Korea.
From the lookout point atop Mount Dora, in the heart of the demilitarised zone that has separated the peninsula since 1953, you can clearly see where South Korea ends and North Korea begins.
The trees that proliferate across Korea’s undulating topography come to an abrupt halt. On the land that sits beyond, a farmer can be seen guiding an ox pulling a plough.
Sealed off from the world economy for 73 years, communist North Korea has resorted to cutting down much of its vegetation to burn for fuel. Democratic South Korea, by contrast, has established deep global trading ties that allow the country to import vital natural resources it cannot produce domestically.
North Korean communism certainly can’t be considered green.
I find these two paragraphs extremely significant.
South Korea may have to import almost all of its crude oil, but the country plays a huge role in refining it into petrol, diesel and jet fuel before shipping it around the world. This means that demand from overseas for Korea’s refined products is greater than ever, which has forced the government to step in. The country’s Ministry of Trade, Industry and Energy has implemented mandatory caps on refined petroleum products.
Of all South Korea’s refined products, kerosene, or jet fuel, is the most in demand. The country is one of the biggest exporters of jet fuel in the world. The US, for instance, relies on it for 70 per cent of its total jet fuel imports.
They could also be problematical for the country, as they will surely need to replace these jet fuel exports with exports of sustainable aviation fuel (SAF).
Most viable processes, that I’ve seen need the following ingredients.
- Lots of hydrogen or masses of GWhs of electricity to make it.
- Some carbon atoms, which can even be captured from the air or a gas-fired power station.
- Some form of Fischer-Tropsch process to force the atoms to make sustainable aviation fuel.
There are several companies that can do this, with British ones seeming to often to be connected to Oxford University.
There is also this Anglo-Korean connection over hydrogen.
I asked Google AI, who are investors in innovative hydrogen production company; HiiROC, which is a spin-out of the University of Hull, and received this answer.
HiiROC, a UK-based developer of “turquoise” hydrogen technology, is backed by a consortium of major industrial and financial players, including Centrica, Melrose Industries, HydrogenOne Capital Growth, Hyundai, Kia, Wintershall Dea, VNG, and Cemex Ventures. The company has raised over £40 million to develop its thermal plasma electrolysis technology.
Note the presence of two of the biggest Korean companies ; Hyundai and Kia.
HiiROC is also five times more efficient than traditional electrolysis.
Google AI says this about South Korean offshore wind.
South Korea is aggressively developing its offshore wind sector, targeting 14.3 GW to 15 GW of installed capacity by 2030, with over 116 projects and 44 GW of capacity under development. The country aims for a 2030 renewable energy share of 20-30%, leveraging floating technology for massive projects like the 3.2 GW Jindo project.
It appears to me, that South Korea will replace their market share of the jet fuel market with sustainable aviation fuel (SAF).
I’m also sure, that if the Koreans need to produce more hydrogen to make more SAF to power the world’s aircraft, Centrica will help them to rent some of our empty seas.
I can see the Koreans, with a little help from their friends, including the UK, dominating the SAF market.
Full fleet Of 27 Hydrogen Trains On German Network Will Not Be Deployed Until 2026 — More Than Three Years Late
The title of this post, is the same as that of this article on Hydrogen Insight.
This is the sub-heading.
Full fleet of 27 hydrogen trains on German network will not be deployed until 2026 — more than three years late
The Alstom fuel-cell trains were ordered back in 2019 in a €500m contract and were supposed to be fully operational in December 2022… but problems have persisted.
To read the rest of the article, I need to register, but from this article, for my argument, I only only need the fact that the trains are three years late.
But the introduction of hydrogen buses into service hasn’t been without its problems in the UK and projects have been dropped.
So have Alstom decided to take a closer control of the technology to bring this flagship project on track? Hence the deal, I talked about in Alstom And Cummins Make A Deal On Hydrogen Rail Technology.
Will the del also breathe new life into the agreement I talked about in Alstom And Eversholt Rail Sign An Agreement For The UK’s First Ever Brand-New Hydrogen Train Fleet?
This is Alstom’s visualisation of the Hydrogen Aventra.
But I certainly think, that a multinational hydrogen-tri-mode train built in Derby by a French-owned company on a proven and reliable 125 mph platform, with German fuel cells, running on Cheshire hydrogen, through spectacular Welsh countryside could be an easy proposition to sell to Fat Controllers.
How Do Alstom Fuel Their Hydrogen Trains?
I have not seen this question answered, so out of curiosity, I asked Google AI and received this answer.
Alstom fuels their hydrogen trains, specifically the Coradia iLint, using high-pressure gaseous hydrogen stored in tanks on the roof. The hydrogen combines with oxygen via fuel cells to generate electricity, which powers the electric traction motor, with only water and heat emitted. The trains refuel at specialized hydrogen stations in roughly 15 minutes.
Key Aspects of Alstom’s Hydrogen Fueling System:
Fueling Station: The trains are powered by specialized hydrogen filling stations, such as the Linde station in Bremervörde, Germany, which supplies gaseous hydrogen.
Refueling Process: The process is designed to be a “drop-in” replacement for diesel, with a filling time similar to that of diesel trains, providing a range of over 1,000 km.
Fuel Cell Technology: Inside the train, a fuel cell module (typically located on the roof) separates hydrogen molecules into protons and electrons, creating a flow of electricity.
Energy Storage: The system uses lithium-ion batteries to store excess energy from the fuel cells and energy recovered from braking.
Hydrogen Source: While some hydrogen is currently produced through conventional methods (steam reforming), there is a strong shift towards using green hydrogen produced from renewable energy on-site.
The Coradia iLint has a top speed of 140 km/h and serves non-electrified lines as a zero-emission alternative to diesel.
Alstom And Cummins Make A Deal On Hydrogen Rail Technology
I asked Google AI about this deal and receive this reply.
On April 2, 2026, Alstom announced the acquisition of Cummins’ hydrogen fuel cell activities specifically dedicated to the rail sector. This strategic move brings the technology and manufacturing capabilities for Alstom’s Coradia iLint hydrogen trains in-house, following a period where Cummins looked to wind down its wider hydrogen business amid losses in its Accelera energy transition segment.
Here are the key details of the deal:
Scope of the Acquisition
Fuel Cell Technology In-House: Alstom acquired the engineering, product, and support capabilities for the fuel cells used in its existing hydrogen train fleets, specifically the Coradia iLint.
Manufacturing Facilities: The deal includes the transfer of Cummins’ fuel cell manufacturing and assembly site in Herten, Germany, which has been producing for Alstom since 2021.
Targeted Support: The acquisition allows Alstom to strengthen its ability to maintain, improve, and provide support for existing hydrogen fleets in Germany, Italy, and France.
Context and Strategy
Securing Supply Chain: After facing maintenance issues with the fuel cells, which previously required sourcing parts from North America, this move gives Alstom direct control over its key technology.
Strategic Pivot: While Cummins moves to pivot away from the wider hydrogen market following losses in its Accelera unit, Alstom continues to focus on hydrogen as a critical solution for replacing diesel trains on non-electrified, long-haul lines.
Commitment to Hydrogen: Despite a 2025 announcement by Alstom that it would pause “further development” of new hydrogen technology due to funding cuts, this acquisition proves that the company remains committed to supporting and enhancing its current, contracted hydrogen train programs.
Future Impact
Reliability Improvements: Alstom plans to leverage this acquisition to accelerate development work, improve the energy management, durability, and reliability of the Coradia iLint fleet, and ensure the success of projects in Germany, Italy, and France.
Market Position: This acquisition solidifies Alstom’s position as a leader in sustainable rail alternatives, even as battery technology has advanced.
I would agree strongly with the future impact.
My First Ride In An Alstom Coradia iLint
In March 2019 in My First Ride In An Alstom Coradia iLint, I said this.
I’m finally, riding in a hydrogen-powered Alstom Coradia iLint train through the German countryside.
Not as quiet as the two battery trains, I’ve ridden, but that’s because It feels to me that the traction motors are crudely under the passengers and cardan shafts are used to drive the wheels!
Battery electric trains with regenerative braking should be virtually free of any mechanical noise. Both the Class 379 and Class 230 battery demonstrators were almost silent. As electricity generated from hydrogen doesn’t appear to generate much noise, then a hydrogen-powered train can also be almost silent.
From talking to fellow passengers on my German trip, it would appear that the train has been very reliable in service.
Conclusion
Alstom are proving hydrogen would work well in a train designed for that purpose, but updating a DMU with a noisy mechanical transmission, possibly isn’t the best to go.
I now believe that Alstom have everything they need to create a 125 mph tri-mode multiple unit.
Adding in today’s article about hydrogen, I have written enough about Bombardier, which is now Alstom, and their future plans, so that they can build an Alstom 125 mph tri-mode Aventra, with with electric, battery or hydrogen power.
It could be the ultimate train.
The Bombardier Aventra And Brexit
The Batteries for Bombardier Electrostar
Parallel Thinking From Bombardier
Bombardier’s Battery Technology
Have Bombardier Got A Cunning Plan For Voyagers?
Bombardier Bi-Mode Aventra To Feature Battery Power
Stadler Flirt And Bombardier Aventra Tri-Modes Compared
Bombardier’s Plug-and-Play Train
Bombardier’s 125 Mph Electric Train With Batteries
Do Bombardier Aventras Have Remote Wake-Up?
Toyota Won’t Give Up On Hydrogen, Teams Up With Truck Giants
The title of this post, is the same as that of this article on TorqueCafe.
This is the sub heading.
Japanese car giant Toyota has signed a non-binding MoU to collaborate with Daimler Truck and Volvo Group on hydrogen fuel cells.
These three paragraphs add more details.
Toyota just won’t let its hydrogen-fuelled dreams die, this week announcing it wants to further develop fuel cell technology with two big players in the heavy vehicle market.
Daimler Truck (makers of Mercedes-Benz, Freightliner, Western Star and Fuso trucks) and the Volvo Group (responsible for Volvo, Mack and Renault trucks), already have a joint venture, cellcentric, which Toyota has signed a non-binding Memorandum of Understanding to join.
Split between equal shareholding, a joint press release said “the combination of the parties’ complementary experience and know-how will support and advance their joint objective to develop, produce and commercialise fuel cell systems for heavy-duty vehicles and other heavy-duty applications with comparable requirements”.
The rest of the article gives a summary of where Toyota are with hydrogen.
It is worth a thorough read.
Backing hydrogen you have Centrica, Ceres, Cummins, Daimler, Hyundai, JCB, INEOS, Kia, Ryse, Volvo, Wrightbus and a few others.
Will they prevail against a cynical world?
I think it will be one iconic vehicle, that excites the world. I will nominate.
- A 1000 km. range hydrogen-powered coach from Mercedes, Solaris, Volvo or Wrightbus.
- A large American-style pickup from Dodge with a Cummins engine or from Toyota.
- A large American-style truck.
- A remodelling of the iconic London new Routemaster bus with a hydrogen Cummins engine by Wrightbus.
- A small affordable hydrogen hatchback from the French, Toyota or the Koreans, based on a fuel cell and an electric transmission.
When I was a child the icon was a dragline called Big Geordie, who is shown in this video.
I suspect for some of the mining projects in the world today, a hydrogen-powered Big Geordie would make a good fist of it.
Centrica Partners With Ceres Power On Solid Oxide Fuel Cells
The title of this post, is the same as this article on gasworld.
This is the sub-heading.
UK multinational energy and services company Centrica is partnering with clean tech firm Ceres Power to accelerate solid oxide fuel cells [SOFCs] production to meet forecasted ‘multi-gigawatt’ demand from industrial customers across Europe.
These three paragraphs indicate the market opportunity, that Centrica feel, that the partnership will fill.
With electricity grid connection delays impacting new industrial, commercial and digital projects, the UK and Europe are experiencing a widening gap between demand and available capacity.
Centrica aims to offer customers high‑efficiency, low‑carbon, grid independent on‑site power that can be deployed much faster than gas turbines or nuclear.
Group Chief Executive Chris O’Shea said by collaborating with Ceres’ technology it sees an opportunity to support data centres, AI and industry with cleaner power at scale. Ceres claims SOFCs can be manufactured and delivered on site to get power online “in months not years”.
It certainly sounds feasible to drop in an appropriate-sized stack of fuel cells and connect them up to the gas main.
These two paragraphs, indicate how Ceres will support Centrica.
Initially, Ceres will support Centrica in expanding a new differentiated service-led model for clean power, providing access to British technology through its expanding network of global manufacturing partners.
Ceres will assist Centrica with opportunities across project origination, installation and commissioning, remote monitoring, predictive maintenance and end of life recycling.
I have a few questions for Google AI.
Do Ceres Fuel Cells Emit Carbon Dioxide?
Google AI replied this.
Yes, Ceres Power has developed Solid Oxide Fuel Cell (SOFC) technology, known as the SteelCell®, that works on natural gas. This technology is specifically designed to be fuel-flexible, capable of converting grid natural gas into electricity at high efficiency.
Key Details About Ceres Fuel Cells and Natural Gas:
Technology Capability: The Ceres SteelCell runs on natural gas, as well as future-focused fuels like hydrogen and biogas.
Application: These fuel cells are used for distributed power generation in homes, businesses, and industrial settings (such as AI data centres).
Efficiency: When running on natural gas, the SOFC systems can achieve an electrical efficiency of around 62%, with total efficiency exceeding 90% when combined with heat recovery.
Emission Reductions: Compared to conventional combustion engines, the technology offers a 30% reduction in carbon emissions.
Current Strategy: As of early 2026, Ceres is focusing on natural gas-fueled SOFCs for stationary power markets, particularly in collaboration with partners like Centrica to address power shortages in the UK and Europe.
While the systems can be used for hydrogen in the long term, they are currently fully functional with natural gas, making them a “bridge” technology for decarbonisation.
A 30% reduction is surely worthwhile!
In What Size Are Ceres Power Holdings Fuel Cells Manufactured?
Google AI replied this.
Ceres Power Holdings’ solid oxide fuel cell (SOFC) technology is manufactured in modular, scalable sizes, with individual stacks ranging from 10-50 kW and commonly deployed in 1-5 MW power modules. These stacks are produced at manufacturing facilities with capacities like 50MW (e.g., with partner Doosan), with plans for up to 100MW annual capacity.
Key manufacturing and size details include:
Cell Component: 30–150W.
Stack: 10–50 kW.
Stack Array/Module: 100–500 kW, up to 1-5 MW modules.
Manufacturing Capacity: 50MW production facility in South Korea (Doosan), with plans for 100MW+ annual capacity in future plants.
Applications: Primarily stationary, distributed power systems for AI data centres, industrial decarbonisation, and commercial buildings.
Ceres licenses its technology to partners like Bosch and Doosan, with cell technology based on low-cost printed steel substrate
How Much Power Does A Top Of The Range MRi Scanner Use?
I am asking this question, as it is surely something you might power with a Ceres fuel cell powered by natural gas.
Google AI replied this.
A top-of-the-range MRI scanner (such as a 3-Tesla or 7-Tesla system) is highly energy-intensive, consuming substantial power 24/7 to maintain its superconducting magnet. During active scanning, power usage often ranges from 25 kW up to 80 kW or more.
Here is a breakdown of the power consumption for high-end MRI scanners:
Power Consumption Breakdown
Idle/Stand-by Mode (24/7): The machine constantly consumes roughly 6 to 7 kW for background cooling (liquid helium refrigeration).
Standard Scanning: Productive scanning sessions typically demand around 25 kW.
High-Demand Scanning: Demanding examinations (e.g., head examinations with EPI sequences or special angles) can cause power usage to surge to 70 kW to 80 kW.
System Total: A 3T MRI, including cooling systems (chillers) and peripheral electronics, might require a 3-phase, 480V, 200A supply—roughly equivalent to the capacity of six modern houses.
Conclusion
This seems to be a deal with a large number of possibilities.
Speaking from my past experience of banks and financing, where the bill is ultimately paid by a reputable individual or company like Shell or BP, I believe that Centrica will have no difficulty in financing lots of these systemsusing instiutions like Lloyds or Deutsche Bank.
The Prototype Affordable Zero-Carbon Small Car Has Just Been Designed
The Wrightbus Ultroliner EU6, is their latest diesel bus.
The product page has this sub-heading.
A Choice Of The
UK’s Most Efficient
Diesel Buses
Two paragraphs give full details of the bus.
The StreetDeck Ultroliner EU6 is available with two ultra low emission efficient diesel engine choices: the new Cummins 6.7 litre 6 cylinder and the current Mercedes 5.1 litre 4 cylinder engine. Our StreetDeck EU6 Ultroliner and its engine choices remains the UK’s favourite. All these buses can be repowered at mid-life to zero-emission BEV technology with NewPower.
The new Cummins ISB6.7 litre six-cylinder diesel engine, married with the latest Voith DIWA.8 NXT 7-speed transmission. Two power options are available: 250Hp / 187Kw, 1000Nm and 300Hp / 224Kw, 1200Nm. With a large 245L fuel tank, this StreetDeck is ready to go the distance, wherever the journey takes it. Its MH3 technology helps lower fuel consumption during frequent stops on busy roads and improves the overall footprint and ride quality. Where ultra clean diesel buses are seen as the only option at this time, there is no better bus than the low emission StreetDeck Ultroliner range.
So you get a modern bus, that can be converted to zero-carbon at an appropriate time.
But nothing is said about conversion to hydrogen, which I believe is the ideal fuel for a large vehicle.
So I asked Google AI, if a Wrightbus Ultroliner can be converted to hydrogen-power, and received this answer.
Yes, the Wrightbus StreetDeck Ultroliner EU6 can be converted to hydrogen power. Wrightbus has engineered the diesel StreetDeck Ultroliner platform to be forward-looking, allowing operators to retrofit these vehicles mid-life with Cummins hydrogen internal combustion engines.
Here are the key details regarding this conversion and technology:
Adaptable Design: The StreetDeck Ultroliner was specifically designed to bridge the gap between traditional diesel and zero-emission options, making it possible to switch to hydrogen or battery-electric powertrains later in the vehicle’s life.
Hydrogen Internal Combustion: Instead of a fuel cell, this retrofit converts the diesel engine to run on hydrogen gas, providing a cost-effective route to zero emissions for existing operators.
Shared Platform: The diesel Ultroliner shares a similar “feel and features” with the purpose-built zero-emission Hydroliner (Hydrogen Fuel Cell) and Electroliner (Battery) buses, making the structural integration of alternative systems more straightforward.
Alternative Conversion Options: Third-party companies, such as Equipmake, specialize in “repowering” Wrightbus StreetDeck models to zero-emission, offering to convert diesel vehicles to electric in a short time frame, although the primary official pathway mentioned by Wrightbus for the Ultroliner is hydrogen-combustion.
The Wrightbus StreetDeck Hydroliner FCEV (Fuel Cell Electric Vehicle) was the world’s first production hydrogen double-decker bus, providing proven technology in cities like Aberdeen, Belfast, and London.
Note.
- The original Cummins diesel engine is converted to hydrogen fuel.
- In Cummins Fuel-Agnostic X Series Platform, I show a Cummins video, which explains their philosophy of convertible engines with trucks.
- Conversion to natural gas is also possible.
- It would appear that the Cummins ISB in the Ultroliner has a hydrogen version, that can be created by changing the fuel system and the cylinder head.
I wouldn’t be surprised, if Cummins told me, that they could make a convertible diesel, that could power a small hatchback.
Out of curiosity, I asked Google AI, “What is the power of a diesel Mini” and received this answer.
The power of a diesel Mini depends on the model (One D, Cooper D, or Cooper SD) and the generation, with power outputs ranging from approximately 88 bhp to 170 bhp. Diesel Minis are known for high torque and excellent fuel economy rather than just top-end speed.
Here is a breakdown of the power figures:
1. MINI Cooper SD (2.0L Diesel)
Power: Typically 143 bhp (105 kW) to 170 bhp (125 kW).
Torque: 305 Nm to 360 Nm (225–265 lb-ft).
Performance: The 170 hp 2.0-litre diesel in the 2015-2018 range is often called a “diesel hot hatch,” featuring a 0-62 mph time of around 7.3 seconds.
2. MINI Cooper D (1.5L – 1.6L Diesel)
Power: Usually between 110 bhp and 116 bhp.
Torque: 270 Nm (199 lb-ft).
Performance: Offers a good balance of fuel economy and punch, with a 0-60 mph time of around 9.4–9.7 seconds.
3. MINI One D (1.4L – 1.5L Diesel)
Power: Approximately 75 bhp to 95 bhp.
Performance: Designed for maximum fuel efficiency and lower tax bands, with lower power output compared to the Cooper models.
Key Takeaways:
Most Powerful: The 2.0L Cooper SD is the most powerful, often producing up to 170 hp.
Torque: Diesel Minis often have high torque at low revs (around 1750rpm), making them quick for overtaking and city driving.
Generation Differences: Older R56 models (2007-2014) often have 1.6L diesel engines, while newer F56 models (2014-2024) use 1.5L or 2.0L engines.
Reliability: These engines are BMW-sourced (N47 or B37/B47) and generally considered reliable.
As there are large numbers of companies around the world, who claim they can convert cars and other vehicles, and engines to hydrogen power.
Out of curiosity, I asked Google AI, “Has Anybody Built A Hydrogen-Powered Mini” and received this answer.
Yes, BMW built a hydrogen-powered MINI Cooper prototype in 2001.
Unveiled at the Frankfurt Motor Show in September 2001, this car was not a fuel-cell vehicle, but rather a hydrogen-burning internal combustion engine car.
Key details about the 2001 MINI Cooper Hydrogen:
Engine: It used a modified version of the MINI’s 1.6-liter four-cylinder engine designed to run on hydrogen.
Technology: It was unique because it used cryogenic liquid hydrogen and injected it while super-cooled, which increased engine efficiency and performance, setting it apart from other hydrogen experiments at the time.
Packaging: Engineers managed to place the contoured hydrogen tank under the rear seats, meaning it did not sacrifice cabin or cargo space compared to a standard Mini.
Legacy: While not mass-produced, it was a significant prototype in BMW’s long-standing research into hydrogen technology.
Other Hydrogen “Mini” Projects:
Mini Mirai RC Car: Toyota and Tamiya built a 1/10th scale hydrogen-fuelled remote-controlled car in 2021. It used a small fuel cell and hydrogen canisters to run for twice the duration of a conventional battery-powered RC car.
Small Engines: Israeli firm Aquarius Engines has developed a 10kg hydrogen-powered engine intended for use as a range extender, which has passed independent testing.
Conclusion
I believe that in the next few years, a serious manufacturer will release a diesel car that can be converted to hydrogen power.
Eventually, this will mean that government can withdraw fossil fuels for road vehicles.
EU Nuclear Push Opens Door For More Pink Hydrogen
The title of this post, is the same as that of this article on H2-View.
These four paragraphs introduce the article.
The European Commission has given a renewed push to nuclear development, which may open the door for more pink hydrogen.
Direct, large-scale pink hydrogen production in Europe is currently very limited, as the industry is still in its pilot and policy-alignment phase. Over 95% of European hydrogen is still produced from fossil fuels, primarily through steam methane reforming.
Speaking at the Nuclear Energy Summit, President Ursula von der Leyen pledged €200m to support private investment in nuclear technologies and unveiled a new European strategy for small modular reactors with the aim that they are operational by the early 2030s. Funding will come from the Emissions Trading System.
“After years of declining investment, we need more to turn the tide,” she said.
It is certainly an article worth giving a good read, as it is a view from the very top.
Bid To Create UK’s First Regional Hydrogen Network
The title of this post is the same as this article on the BBC.
This is the sub-heading
Four energy companies are working together to bid for government funding to develop the UK’s first regional hydrogen transport and storage network.
This two paragraphs add more details to the article.
National Gas, Centrica, Equinor and SSE Thermal aim to secure about £500m of funding to develop the network, which will connect sites across the Humber region.
“This is a competitive process that will determine where the UK’s first integrated hydrogen network is built,” a spokesperson for the four companies said.
Note.
- There are already several hydrogen projects in the area including Aldbrough Hydrogen Storage, H2H Saltend, and Ferrybridge and Keadby Next Generation Power Stations.
- The local MPs seem in favour.
- In Could Doncaster Sheffield Airport Become A Hydrogen Airport?, I laid out my reasons, why Doncaster Sheffield Airport could become a hydrogen airport.
I can see this hydrogen cluster having a big future.
New Baltic Sea Interconnector On Horizon As Lithuania, Latvia, and Germany Plan Cross-Border Link
The title of this post, is the same as that of this article on offshoreWIND.biz.
This is the sub-heading.
Lithuania, Latvia, and Germany are planning a joint offshore interconnector that would enable electricity trading between the Baltic countries and Germany and allow for the integration of up to 2 GW of offshore wind capacity in Lithuania and Latvia
These first two paragraphs add more detail to the article.
The energy ministers of the three countries signed a joint declaration of intent on 18 February, paving the way for the development of the Baltic-German PowerLink interconnector, which would, in addition to electricity trading and offshore wind capacity integration, also enable the expansion of onshore renewable energy capacity.
The Lithuanian, Latvian, and German transmission system operators (TSOs) – Litgrid, Augstsprieguma tīkls and 50Hertz – agreed to assess the feasibility of the hybrid electricity interconnection.
As Germany, has the following connections under development in the West.
- AquaVentus to Aberdeen, Humberside, Denmark, Norway and The Netherlands.
- NeuConnect to the Isle of Grain In England.
- GriffinLink, which is an offshore link to England.
The Germans seem to be putting themselves at the centre of an energy distribution system, that has the capability to stabilise European and UK electricity for thousands of years. Especially, if the network grows to include more countries.
This paragraph says this about the Baltic-German PowerLink project.
The Baltic-German PowerLink project concept developed by Litgrid, Augstsprieguma tīkls, and 50Hertz includes a 2 GW, approximately 600 kilometres long hybrid offshore connection, with the connection point in the Baltic States planned to be on the border between Lithuania and Latvia. The exact location is to be determined after technical studies.
Note.
- The interconnectors may be long, but they are not longer than anything built successfully before in European waters.
- The UK and the Island of Ireland are well-linked.
- There would appear to be no need for challenging projects like the Morocco-UK Power Project
I suspect that Germany will get the energy it needs and the British Isles will get a nice little earner.
If Europe is generating large amounts of wind and solar energy with its variable output it will need lots of energy storage.
What Countries Have The Terrain For Pumped Storage Hydro In Europe?
I asked Google AI and received this answer.
Key countries with ideal, high-elevation terrain and significant existing or planned capacity include:
Alpine Region (The Heart of European Pumped Storage):
Switzerland: Extremely high capacity due to steep, mountainous landscapes and significant water sources, hosting the world’s oldest working pumped storage plant.
Austria: Heavily mountainous, it is a major player in PSH expansion and modernization.
France: Home to one of Europe’s largest, the Grand Maison hydroelectric power station.
Italy: Holds high capacity with numerous planned projects.
Germany: Strong existing infrastructure.
Southern Europe:
Spain: Features some of Europe’s largest plants (e.g., La Muela/Cortes-La Muela).
Portugal: Significant recent investment in large-scale projects like the Tâmega complex.
Other Potential Areas:
Norway: High potential due to its mountainous, water-rich terrain.
United Kingdom: High project volume currently under construction.
Balkans & Central Europe:
Countries like Bulgaria, Romania, and the Czech Republic have suitable terrain for further development.
These countries benefit from significant hydraulic head (steep drop) and natural or artificial reservoir potential, making them ideal for storing energy for peak consumption hours.
Note.
- As expected, the Alpine region is Top of the League.
- The UK is holding its own despite its small mountains.
- There is a lot of potential to be developed.
But then Electric Mountain in Snowdonia is certainly at the top table of pumped storage systems despite being built in the 1980s.
What Countries Have The Terrain For Hydrogen Storage In Europe?
I asked Google AI and received this answer.
Key European countries with suitable geological terrain—specifically salt caverns and depleted gas fields—for large-scale, underground hydrogen storage include Germany, the Netherlands, Denmark, the United Kingdom, and France. Other significant regions for storage potential include Spain, Hungary, and Austria, which are developing porous storage facilities.
Key Regions & Terrain Types:
Salt Caverns (North-Western Europe): Germany, the Netherlands, Denmark, France, and the UK have substantial salt deposits suitable for creating caverns, identified as cost-efficient for large-scale storage.
Depleted Gas Fields (Porous Rock): The Netherlands, Germany, and parts of Central/Southern Europe (Spain, Hungary) have significant capacity in existing porous storage, particularly in the North Sea region.
Specific Projects: Germany (Uniper’s Krummhörn project), Netherlands (HyStock), and France (HYPSTER at Etrez) are active, with Spain and Denmark emerging as major hydrogen hubs.
Capacity Potential: The Netherlands, for instance, holds massive potential (35-60 TWh) due to its offshore and onshore depleted fields.
Salt cavern projects, which offer high-deliverability storage, are heavily concentrated in the North-Western European industrial corridor.
I was lucky enough have a tour of ICI’s salt mine in Cheshire, when I worked there in the 1960s and I remember these facts from those days.
- There was enough salt in the ground under Cheshire to last several thousand years.
- Most salt was extracted from boreholes, for making chlorine using electrolysis and the Castner-Kellner process.
- Hydrogen was a by-product and much of it was mixed with coal gas to raise steam for the works.
The same technique used to make boreholes to extract the salt, is used to hollow caverns in the salt to store gases like hydrogen.
Once, when they were digging salt out of the salt mine at Winsford, a worker broke into an unmarked borehole and ICI nearly lost the mine because of the water rushing in.
Two stories stand out from the rescue of the mine.
- There was a need for dry clothes for all the workers, so ICI took a truck to Marks & Spencer in Northwich and emptied it of anything they might need. I was told the story enriched with plagues of locusts.
- A Ford Transit was found to have travelled a few thousand miles underground in axle deep salt slurry. Rather, than scrap it and buy another, it was offered back to Ford, who were delighted to swap it for a new one. I heard that Ford said, that the accelerated corrosion research would have taken many years, if done on the roads.
Always think out of the box.
The Anonymous Widower 