The Anonymous Widower

Alstom Plans To Operate Its Own Passenger Train Service In The UK For The First Time

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

These two bullet points, act as sub-headings.

  • Alstom is partnering with SLC Rail to form a new open access rail operation between North Wales, Shropshire, the Midlands and London
  • Formal application now being submitted to the Office of Rail and Road (ORR) with passenger service sought from 2025

These are the first three paragraphs.

Alstom, global leader in smart and sustainable mobility, plans to operate a new passenger rail service across England and Wales. Working in partnership with consultancy SLC Rail, the open access operation will be known as Wrexham, Shropshire and Midlands Railway (WSMR).

As the country’s foremost supplier of new trains and train services, and a leading signalling and infrastructure provider, Alstom will operate its own rail service in the UK for the first time.

WSMR is seeking to introduce direct connectivity to and from North Wales, Shropshire, the Midlands and London that doesn’t exist today, linking growing communities and businesses, and making rail travel more convenient, enjoyable and affordable.

I can’t remember a service proposal being put forward by a train manufacturer since the privatisation of UK’s railways in the 1990s.

This is some more information and my thoughts.

The Route

This paragraph from the press release, describes the route.

The proposal envisages a service of five trains per day in each direction Monday to Saturday, with four travelling both ways on Sundays. Trains will stop at Gobowen, Shrewsbury, Telford Central, Wolverhampton, Darlaston, Walsall, Coleshill Parkway, Nuneaton and Milton Keynes on their journey between Wrexham General and London Euston.

Note.

  1. The proposed call at the new Darlaston station.
  2. The route is electrified between Euston and Nuneaton and Walsall and Wolverhampton.
  3. Much of the route North of Nuneaton is on tracks with a maximum speed of 70-80 mph.

The route is in these sections.

  • Euston and Nuneaton – 96.7 miles – electrified
  • Nuneaton and Walsall – 26.7 miles
  • Walsall and Wolverhampton – 6.7 miles – electrified
  • Wolverhampton and Shrewsbury – 29.7 miles
  • Shrewsbury and Wrexham General – 30.3 miles

That is a total of 190.1 miles or 380.2 miles round trip.

I suspect that the service will need bi-mode trains.

Should The Service Call At Wellington?

This article on the BBC is entitled Rail Company Urged Not To Forget Wellington.

This is the sub-heading.

A rail company which is bidding to bring back a direct service between Shropshire and London has been urged not to forget a town.

These are the first three paragraphs.

Wrexham, Shropshire and Midlands Railway said it was preparing to apply to the government to run the service.

Trains would stop at Gobowen, Shrewsbury, Telford, Wolverhampton, Walsall, Coleshill and Nuneaton.

But Telford and Wrekin Council said the omission of Wellington as a stop was “short-sighted”.

Although Wellington is smaller than than Shrewsbury and Telford, it looks like a bit of analysis would provide a solution, that would be acceptable for all parties.

The Trains

In the press release, this phrase is used.

positive impact to both communities and the environment.

I can’t see any more electrification being erected on the route, so the trains will need to be bi-mode.

  1. Bi-mode diesel trains won’t have a positive impact on the environment.
  2. As the route between Wolverhampton and Wrexham General is not electrified, a battery-electric train would need a range of at least 60 miles or 120 miles for the round trip, if there were no charging at Wrexham General.
  3. But Alston are developing a Hydrogen Aventra, which I wrote about in Alstom And Eversholt Rail Sign An Agreement For The UK’s First Ever Brand-New Hydrogen Train Fleet.

So could Alstom be using this route to trial and showcase their new Hydrogen Aventra?

I believe that the route will be very suitable for a hydrogen train.

  • Changeover between electric and hydrogen power can always take place in a station.
  • All hydrogen refuelling could be performed at one end of the route.
  • A large proportion of the UK’s green hydrogen is produced by INEOS at Runcorn, which is less than fifty miles from Wrexham. A refuelling tanker could supply the train, as they do on some hydrogen routes in Germany.
  • London has only small amounts of hydrogen infrastructure.

I suspect that refuelling will be done at the Wrexham end of the route.

This Alstom visualisation shows the train.

But it is only a three-car train.

  • That is not a problem, as Aventras can be lengthened as required to the length required for the number of passengers.
  • Some Aventras, like the Class 701 trains for South Western Railway, have even been ordered as ten-car trains.
  • Two three-car trains may also be the ideal capacity, running as a six-car train.

So capacity will not be a problem.

If it is assumed that Alstom’s trains for the WSMR route, can use the overhead wires, where they exist, each trip between Wrexham General and London will require a total of 86.7 miles or 140 kilometres of running on hydrogen.

  • A round trip will therefor require 280 kilometres of running on hydrogen.
  • But between London Euston and Nuneaton, it will just be another electric train.
  • I suspect that like the similar Class 730 train, it will be capable of 110 mph on the West Coast Main Line.
  • Alstom’s Coradia iLint hydrogen train has a range of around a 500-800 kilometres on hydrogen.
  • The WSMR trains will probably be 100 mph trains using hydrogen on a route, where that speed is possible.

So if a Hydrogen Aventra has a similar range to the Coradia iLint, it will be able to do two round trips before refuelling.

How Long Will The Service Take?

West Midlands Trains, who use the similar Class 730 trains take one hour and eleven minutes between London Euston and Nuneaton with a single stop at Milton Keynes Central.

As the WSMR trains will use the same route, I suspect the same time can be used.

As Nuneaton and Wrexham General are 93.4 miles apart a table can be created showing the time for the rest of the journey for different average speeds

  • 50 mph – 1 hour 52 minutes – 3 hours 3 minutes.
  • 60 mph – 1 hour 33 minutes – 2 hours 44 minutes.
  • 70 mph – 1 hour 20 minutes – 2 hours 31 minutes.
  • 80 mph – 1 hour 10 minutes – 2 hours 21 minutes.

Note.

  1. The first time is the Nuneaton and Wrexham General time and the second time is the overall journey time.
  2. Typical Avanti West Coast services via Crewe and a change at Chester, take between two-and-a-half and three hours.

I suspect, if the WSMR trains can keep the speed up through the Midlands, that two hours and 30 minutes could be possible.

Could The Hydrogen Aventra Run At 125 mph Under The Wires?

In March 2018, I wrote Bombardier Bi-Mode Aventra To Feature Battery Power, which was based on this article in Rail Magazine.

These are a few points from the article.

  • Development has already started.
  • Battery power could be used for Last-Mile applications.
  • The bi-mode would have a maximum speed of 125 mph under both electric and diesel power.
  • The trains will be built at Derby.
  • Bombardier’s spokesman said that the ambience will be better, than other bi-modes.
  • Export of trains is a possibility.
  • Bombardier’s spokesman also said, that they have offered the train to three new franchises. East Midlands, West Coast Partnership and CrossCountry.

Have Alstom looked at what they bought from Bombardier and decided the following train is possible?

  • Five-cars or what the customer needs.
  • 125 mph under the wires.
  • Running on hydrogen away from the wires.
  • 100 mph on tracks without electrification.

Obviously, maximum speeds  would depend on track limits.

Looking at 125 mph Avanti West Coast trains that have a Milton Keynes stop between London Euston and Nuneaton, they can reach Nuneaton ten minutes quicker than West Midlands Trains 110 mph Class 730 trains.

Two hours and 30 minutes between London Euston and Wrexham is looking increasingly possible.

Are we seeing an audacious proposal from Alston to sell new trains to CrossCountry and a host of other franchises?

Conclusion

London Euston and Wrexham would appear to be an excellent route for an Aventra-based hydrogen train.

  • It can probably cruise at 110 mph on the West Coast Main Line between London Euston and Nuneaton.
  • All switchovers between electrification and hydrogen can be performed in electrified stations.
  • Hydrogen would only be used North of Nuneaton.
  • The train can be refuelled at Wrexham General, with fuel supplied from INEOS at Runcorn.
  • Given the typical 1000 km. range of hydrogen trains, a train can probably do three round trips without refuelling.

I can see this being a service with an excellent operational record.

 

March 15, 2024 Posted by | Hydrogen, Transport/Travel | , , , , , , , , , , , , , , , , , , , | 4 Comments

A Funny Wet Week

I’ve had a funny few days as regards my health.

Tursday morning, my INR was 2.1.

On Friday night, I wasn’t sleeping very well and got up at three on Saturday morning. But after a couple of mugs of tea, I was feeling a lot better.

I had my usual Saturday morning breakfast in Leon on Moorgate, but I did get slightly confused with my shopping in Marks & Spencer. I put this down to my eyesight having an off day. Is that normal after two cataract operations?

I slept better on Saturday night! But was this because I went to bed before instead of after Match of the Day and then watched it on Sunday morning.

On Sunday morning, I went out to do a bit of shopping, but it was really just to get out and then it was walking in the pouring rain.

Monday was a quiet day, after breakfast in Leon on Moorgate, I wrote for most of the day. My INR was a bit low at 2.2.

Tuesday morning, it was a repeat of Friday night and I got up at four and had a couple of mugs of tea. It was another breakfast in Leon on Moorgate and a visit to M & S. After I returned, I wrote for most of the day, as it was too wet to go outside.

In the afternoon, I started to get a bit unsteady on my feet and even thought about calling 999. But after two mugs of tea and a can of Adnams, I regained my balance and never fell. My blood pressure was fine and the only unusual thing, was that my left food was quite red. But it does this sometimes.

Wednesday was uneventful and I had lunch with a friend at Cote in Sloane Square.

Today, Thursday my INR is down to 2.

I feel OK, but it does seem, that for some reason my INR has tended to slump during the week.

I just wonder if my leaky skin, just lets water out, which surely must lower the INR.

Does my foot go red, as the red blood corpuscles are too big to get through my skin?

March 14, 2024 Posted by | Health | , , , , , | 4 Comments

Dogger Bank D Welcomes Confirmation Of Grid Connection Location

The title of this post, is the same as that of this press release from SSE Renewables.

This is the sub-heading.

Project team now focusing full attention on electrical transmission system connection.

These four paragraphs describe the proposed connection to the National Grid.

SSE Renewables and Equinor have welcomed confirmation of a grid connection location from the Electricity System Operator (ESO) for a proposed fourth phase of the world’s largest offshore wind farm.

Dogger Bank D will now connect into Birkhill Wood, a proposed new 400kV substation located in the East Riding of Yorkshire which will be built as part of National Grid’s Great Grid Upgrade.

The announcement follows the publication of an impact assessment for the South Cluster by ESO, relating to energy projects which are due to be electrically connected off the east coast of England.

With the location of a grid connection confirmed, Dogger Bank D will now focus its full attention on connecting to the electrical transmission system.

This is a big change from December 2023, when I wrote Plans for Hydrogen Development At Dogger Bank D Gain Ground, which indicated that Dogger Bank D would be used to produce hydrogen, so the grid connection wouldn’t be needed.

Using A Offshore Hybrid Asset Between the UK And Another European Country

This is the next paragraph on the SSE Renewables press release.

The project is also exploring the future possibility of the development of Dogger Bank D to be coordinated with an Offshore Hybrid Asset between the UK and another European country’s electricity market to form a multi-purpose interconnector. This option would increase energy security for the UK and reduce the need to curtail offshore wind output in times of oversupply on the GB network.

Note that just over the boundary of the UK’s Exclusive Economic Zone are the Dutch and German Exclusive Economic Zones.

It is not unreasonable to believe that UK, Dutch and German grid could all be connected on the Dogger Bank.

Connecting Everything Up At Birkhill Wood

This is the next paragraph on the SSE Renewables press release.

The project team are undertaking a site selection process to identify potential cable corridors and where other onshore infrastructure associated with the grid connection at Birkhill Wood may be sited. Consultation will be held later this year to introduce the connection proposals to the local community.

At least now, with the connection to Birkhill Wood confirmed, SSE and Equinor will be able to supply any electricity generated at Dogger Bank D to the UK grid, up to limit of the connection.

The Value Of Electricity That Could Be Generated At Dogger Bank D

Consider.

  • The wind farm has a capacity of 2 GW or 2,000 MW.
  • There are 365 days in most years.
  • There are 24 hours in the day.
  • This means that 17, 520,000 MWh could be generated in a year.
  • A large wind farm like Hornsea One has a twelve month rolling capacity factor of 46.6%.
  • Applying this capacity factor says that 8,164,320 MWh will be generated in a year.
  • The Contract for Difference Round 6 for this electricity will be £73/MWh.

Applying that figure gives a yearly turnover of £ 595,995,360 or £ 297,997,680 per installed GW.

It is not unreasonable to assume that half of this electricity were to be exported to power Germany industry.

It could be a nice little earner for the Treasury.

March 14, 2024 Posted by | Energy | , , , , , , , , , | 3 Comments

Contracts Signed For Eastern Green Link 2 Cable And Converter Stations

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

These four bullet points, act as sub-headings.

  • Eastern Green Link 2 (EGL2) is a 525kV, 2GW high voltage direct current (HVDC) subsea transmission cable from Peterhead in Scotland to Drax in England delivered as a joint venture by National Grid and SSEN Transmission
  • The joint venture has signed a contract with the Prysmian Group to supply around 1,000km of cable for the project and a contract with Hitachi Energy and BAM for the supply of converter stations at either end of the subsea cable
  • Contract signing is a significant milestone for the project as it progresses towards the delivery phase
  • EGL2 will be the longest HVDC cable in the UK and the UK’s single largest electricity transmission project ever, providing enough electricity to power two million UK homes

This paragraph outlines the project.

EGL2, a joint venture between SSEN Transmission and National Grid Electricity Transmission (NGET), has reached another milestone in the development of a new subsea electricity superhighway after sealing contracts this week with specialist HVDC cable supplier, Prysmian, and with Hitachi Energy and BAM for the supply of converter stations at either end of the project.

These four paragraphs add more detail.

EGL2 will see the creation of a 525kV, 2GW HVDC subsea transmission cable from Peterhead in Scotland to Drax in England. The longest HVDC cable in the UK and the UK’s single largest electricity transmission project ever, it will provide enough electricity to power two million UK homes.

Prysmian has confirmed it has the capability to deliver the project with its manufacturing facilities for the production of the HVDC cable and its cable laying vessels for the installation in the timescale required for EGL2 to meet its targeted energisation date in 2029, supporting the timely delivery of this project and mitigating risks associated with global constraints in the HVDC supply chain.

Hitachi Energy is partnering with BAM to provide the engineering works and technology for the HVDC converter stations which form the terminals for the HVDC cable and convert direct current to the alternating current used in the onshore transmission network. This latest milestone is another significant step as the project moves towards delivery and, following final approval from Ofgem, work is expected to commence later this year, with a targeted operational date of 2029.

The subsea HVDC cable system is approximately 436km in length with new converter stations at either end to connect it into the existing transmission network infrastructure. HVDC technology provides the most efficient and reliable means of transmitting large amounts of power over long distances subsea.

Note.

  1. EGL2 can handle 2 GW.
  2. There is a targeted operational date of 2029.
  3. Eastern Green Link 2 now has its own web site.
  4. Most of these links now seem to be HVDC.

A map in the press release, shows the undersea route may be shorter.

It  also appears to me, that moving electricity around the UK under the sea, is possibly the most environmentally-friendly and least intrusive way to do it.

We already have four HVDC interconnectors.

There will be many more,

 

 

March 13, 2024 Posted by | Energy | , , , , , , , | 9 Comments

Ørsted Secures Exclusive Access To Lower-Emission Steel From Dillinger

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

This is the sub-heading.

Ørsted will be offered the first production of lower-emission steel from German-based Dillinger, subject to availability and commercial terms and conditions. The steel plates are intended to be used for offshore wind monopile foundations in future projects.

These three paragraphs outline the deal.

Under a large-scale supply agreement entered into in 2022, Ørsted will procure significant volumes of regular heavy plate steel from 2024, giving the company access at scale to and visibility of the most crucial raw material in offshore wind while supporting Dillinger to accelerate investments in new lower-emission steel production, according to Ørsted.

The Danish renewable energy giant expects to be able to procure lower-emission steel produced at Dillinger’s facility in Dillingen, Germany, from 2027-2028.

Taking the current technology outlook into account, the reduction of the process-related carbon emissions from production is expected to be around 55-60 per cent compared to conventional heavy plate steel production, Ørsted said.

Increasingly, we’ll see lower emission steel and concrete used for wind turbine foundations.

This press release on the Dillinger web site is entitled Historic Investment For Greater Climate Protection: Supervisory Boards Approve Investment Of EUR 3.5 billion For Green Steel From Saarland.

These are two paragraphs from the press release.

Over the next few years leading up to 2027, in addition to the established blast furnace route, the new production line with an electric arc furnace (EAF) will be built at the Völklingen site and an EAF and direct reduced iron (DRI) plant for the production of sponge iron will be built at the Dillinger plant site. Transformation branding has also been developed to visually represent the transformation: “Pure Steel+”. The message of “Pure Steel+” is that Saarland’s steel industry will retain its long-established global product quality, ability to innovate, and culture, even in the transformation. The “+” refers to the carbon-neutrality of the products.

The availability of green hydrogen at competitive prices is a basic precondition for this ambitious project to succeed, along with prompt funding commitments from Berlin and Brussels. Local production of hydrogen will therefore be established as a first step together with the local energy suppliers, before connecting to the European hydrogen network to enable use of hydrogen to be increased to approx. 80 percent. The Saarland steel industry is thus laying the foundation for a new hydrogen-based value chain in the Saarland, in addition to decarbonizing its own production. In this way, SHS – Stahl-Holding-Saar is supporting Saarland on its path to becoming a model region for transformation.

It sounds to me, that Tata Steel could be doing something similar at Port Talbot.

  • Tata want to build an electric arc furnace to replace the blast furnaces.
  • There will be plenty of green electricity from the Celtic Sea.
  • RWE are planning a very large hydrogen electrolyser in Pembroke.
  • Celtic Sea offshore wind developments would probably like a supply of lower emission steel on their door-step.

I would suspect, that Welsh steel produced by an electric arc furnace will match the quality of the German steel, that is made the same way.

March 13, 2024 Posted by | Energy | , , , , , , , , , , , , , | Leave a comment

Japan Expands Offshore Wind Development Into Exclusive Economic Zone

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

This is the sub-heading.

The Japanese Government has passed an amendment to the “Act on Promoting the Utilization of Sea Areas”, expanding the area for setting up offshore wind to the Exclusive Economic Zone (EEZ).

These two paragraphs give more details.

The Japanese government aims to deploy 10 GW of offshore wind capacity by 2030 and 30-45 GW by 2040, including floating wind, as part of its target to reach net-zero emissions by 2050.

The new legislation would allow wind farms to be installed further out to sea from current territorial and internal waters, according to a joint statement by the government, the Ministry of Economy, Trade and Industry and the Ministry of Land, Infrastructure, Transport and Tourism.

The Japanese seem to have devised a simple bid process, that gives rights to generate electricity for thirty years.

But then as a Director of Lockheed told me thirty years ago, the Japanese don’t have the same high levels of lawyers that the US, UK and other countries have, so they can move a lot faster and are easier to do business with.

This Wikipedia entry is entitled Wind Power in Japan.

This is the opening paragraph.

In Japan’s electricity sector, wind power generates a small proportion of the country’s electricity. It has been estimated that Japan has the potential for 144 gigawatts (GW) for onshore wind and 608 GW of offshore wind capacity. As of 2020, the country had a total installed capacity of 4.2 GW.

From the potential of 608 GW of offshore wind capacity, it looks like Japan is in a very similar position to the UK and the Japanese can also reap the wind.

March 13, 2024 Posted by | Business, Energy | , , , , | Leave a comment

National Gas To Trial Gravitricity’s H2 Storage Solution

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

This is the sub-heading.

Gravitricity’s H2FlexiStore system for underground hydrogen storage could see a pilot built in 2025 after National Gas secured Ofgem funding to explore the technology.

There is then a graphic, which gives a good visual explanation.

The patented system uses lined geological shafts to store up to 100 tonnes of pressurised hydrogen at 220 bar, equivalent to about 3.33GWh of energy. Unlike natural storage such as salt caverns and disused gas fields, the shafts can be sited anywhere. Gravitricity has previously stated its preference for co-locating the storage near to renewable generation and potential major consumers of hydrogen such as heavy industry.

I can see that this simple system can have a lot of diverse uses.

In Centrica Completes Work On 20MW Hydrogen-Ready Peaker In Redditch, I talked about how Centrica had refurbished a decommissioned peaker plant.

One of these stores would keep a 20 MW peaker plant running for a week.

It would also work well with a HiiROC hydrogen system.

March 12, 2024 Posted by | Energy Storage, Hydrogen | , , , , | Leave a comment

Aurizon Secures Funding To Develop Next-Generation Freight Trains Using Renewable Energy

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

These five paragraphs outline the project.

Australia’s largest rail freight company Aurizon, today received a major boost to its program to develop the next generation of Australian freight trains, aiming to replace diesel fuel with renewable energy sources on its locomotive fleet.

Aurizon has secured a $9.4 million grant from the Australian Renewable Energy Agency (ARENA) to develop, test and trial a battery electric tender (BET) to be used in conjunction with a modified locomotive. (refer graphic below).

The tender – essentially a big battery-pack on wheels – will couple with the modified locomotive to operate as a hybrid unit using both diesel and battery-electric power sources. The tender’s battery will also harness re-generative energy captured as the train travels down grades and brakes as part of normal operation.

The ARENA grant represents half of the required funding for the ‘Battery Powered Tender for Heavy Haul Fleet Decarbonisation’ project, with the balance of the investment to be funded by Aurizon. The battery-electric tender and modified locomotive project will be built by Aurizon and technology project partner, Alta Battery Technology (Alta) at a facility in Australia, with design and technology inputs from Alta.

Aurizon appreciates the Federal Government making funding available to support the development of a range of new zero emissions technologies in the transport sector, including technologies that can be developed for application in rail-based freight supply chains that are integral to Australia’s export and domestic industries that rely on transport services.

At a first glance it appears to be suited to Aurizon and its long routes with heavy freight trains across Australia.

These are some more specific thoughts.

Alstom Have Built A Train With a Hydrogen Tender

In From 2025, Nestlé Waters France Will Use The First Hydrogen-Powered Freight Train Through An Innovative Solution Developed by Alstom and ENGIE, I describe a train powered by an electric locomotive with an attached hydrogen power unit.

The Future Of The Class 68 Locomotives

Could these be given a reduced-carbon second life, by developing a specialised tender?

I wrote about this in The Future Of The Class 68 Locomotives.

I suspect Stadler, who seem to be excellent innovators will be watching.

There Seems To Be A Lot Going On In Australia

I have written several posts about decarbonisation of freight trains in Australia.

The big mining companies certainly seem keen to decarbonise.

 

 

March 12, 2024 Posted by | Transport/Travel | , , , , , , , , | 1 Comment

ORR: Open Access Services Given Green Light Between London And Stirling

The title of this post is the same as that of this press release from the Office of Rail and Road.

This is the sub-heading.

The latest access decision by the Office of Rail and Road (ORR) provides more services for rail passengers travelling between London and central Scotland.

These five paragraphs detail the ORR’s decision.

ORR has today (7 March) given the go-ahead for Grand Union Trains, an open access operator, to start a new train service between London and the city of Stirling, from June 2025. ORR’s decision will offer more choice to passengers, bring private sector investment to the railway and increase competition.

Grand Union Trains will introduce four new return services per day between London Euston and Stirling stations. These services will also call at Milton Keynes Central, Nuneaton, Crewe (subject to agreement between Grand Union Trains and Network Rail), Preston, Carlisle, Lockerbie, Motherwell, Whifflet, Greenfaulds and Larbert. Larbert, Greenfaulds and Whifflet will receive their first direct services to London.

ORR found that the proposed services would increase choice for passengers, significantly increasing direct journey opportunities to and from London and central and southern Scotland, while making use of existing capacity on the network.

The new services will be the first run by an open access operator on the West Coast Mainline. Open access operators run services independently of government funding as they do not have a franchise agreement with government.

Following ORR’s decision to approve new Grand Union Trains services between Carmarthen in south Wales and London Paddington in 2022, ORR has now approved open access services on three of Britain’s major routes.

Note.

  1. The Grand Union service appears to be running into London Euston. Earlier plans had it terminating at Queen’s Park station.
  2. Larbert, Greenfaulds and Whifflet will receive their first direct services to London.
  3. London Euston and Stirling is electrified all the way.
  4. The third open access service, that the ORR has approved is the Lumo service between King’s Cross and Edinburgh via the East Coast Main Line.

I have a few thoughts.

Stirling Is An Ideal Place To Explore Central Scotland By Train

In Stirling, I give the reasons, why I spent a couple of days in Stirling, when I wanted to visit several places in Central Scotland.

Note.

  1. Stirling has direct services to Aberdeen, Dundee, Edinburgh, Glasgow, Inverness and Perth.
  2. Aberdeen is one hour and 15 minutes away.
  3. Dundee is just 63 minutes away.
  4. Edinburgh is just 48 minutes away.
  5. Glasgow is just 39 minutes away.
  6. Inverness is two hours and 46 minutes away.

Stirling has about a dozen affordable hotels and guest houses within walking distance of the station, as this map shows.

Stirling would appear to have got Central Scotland covered.

Could The Train Serve Gleneagles?

Gleneagles is about twenty minutes North of Stirling and is served by the Caledonian Sleeper from London.

This Google Map shows the area around Gleneagles station.

Note.

  1. Gleneagles station is at the bottom of the map.
  2. The red arrow indicates the famous Gleneagles hotel.
  3. The pink dots are other hotels.
  4. Airbnb lists several very splendid properties in the varea.

Not everybody, who goes to the Gleneagles area will be exceedingly rich and I could see the Gleneagles area generating substantial business for Grand Union Trains. I suspect the best way to serve Gleneagles would be a zero-emission coach from Stirling.

Along The Motherwell And Cumbernauld Line

Between Motherwell and Stirling, a lot of the route used is on the Motherwell and Cumbernauld Line.

  • The line is fully-electrified.
  • It is only 28.9 miles between Motherwell and Stirling.
  • \cumbernaukd and Motherwell takes 20 minutes.

I do wonder, if extra stops might be worthwhile.

Motherwell Has Good Connections To Edinburgh And Glasgow

As well as Stirling, Motherwell has good connections to both Edinburgh and Glasgow, so some passengers might find their most convenient route involves a change at Motherwell.

Nuneaton And Scotland Would Get A New Service

Nuneaton has been named by Avanti West Coast, as a place that needs more trains, as it connects with the service between Birmingham and Stansted Airport, via Coleshill Parkway, Leicester, Peterborough, March, Ely and Cambridge.

I suspect that, Nuneaton will become an interchange, between East Anglia and, the North West and West Scotland.

Milton Keynes And Scotland Should Get An Improved Service

Consider.

  • It appears that all Avanti West Coast services between Milton Keynes and Scotland, go via Birmingham.
  • I suspect that Grand Union’s route using the Trent Valley Line could be faster with similar trains.
  • Creating a new route between Milton Keynes and Stirling could be a good move, as it gives one-change access to much of Central Scotland.
  • Milton Keynes has good local connections to places like Northampton, Rugby, Tring and Watford Junction.
  • Milton Keynes will be a stop on the new East-West Railway.
  • From many stations, it will be quicker to go via Milton Keynes rather than Euston.

I suspect Milton Keynes could be a nice little earner.

Will Grand Union’s Trains Be Fitted With Digital Signalling?

Consider.

  • At some point in the next ten years the West Coast Main Line will be fitted with digital signalling, to enable trains to run at 140 mph on selected parts of the route.
  • Digital signalling will allow extra services between London Euston and Motherwell.
  • Motherwell and London Euston is 388 miles.

I suspect, that Grand Union’s Trains will need to be fitted with digital signalling, so they can save time on services and possibly add in a few more.

It will add costs, although the faster speed will surely attract passengers.

Will Grand Union’s Trains Be Electric?

There are these train services going between England and Scotland.

  • Avanti West Coast – London Euston to Edinburgh Waverley via Birmingham New Street – 7 tpd – Class 390 – Electric
  • Avanti West Coast – London Euston to Glasgow Central via Birmingham New Street – 5 tpd – Class 390 – Electric
  • Avanti West Coast – London Euston to Glasgow Central via Trent Valley – 1 tph – Class 390 – Electric
  • CrossCountry – Plymouth to Edinburgh Waverley – 1 tph – Class 220/221 – Diesel – Uses diesel all the time
  • LNER – London King’s Cross/Leeds to Aberdeen – 4 tpd – Class 800 – Bi-mode – Uses diesel North of Edinburgh
  • LNER – London King’s Cross to Inverness – 1 tpd – Class 800 – Bi-mode – Uses diesel North of Stirling
  • LNER – London King’s Cross to Edinburgh Waverley – 3p2h – Class 800 – Bi-mode or Class 801 – Electric
  • LNER – London King’s Cross to Glasgow Central – 1 tpd – Class 801 – Electric
  • LNER – London King’s Cross to Stirling – 1 tpd – Class 801 – Electric
  • Lumo – London King’s Cross to Edinburgh – 5 tpd – Class 803 – Electric
  • TransPennine Express – Newcastle to Edinburgh Waverley – 7 tpd – Class 802 – Bi-mode
  • TransPennine Express – Liverpool Lime Street to Glasgow Central – 2 tpd – Class 397 – Electric
  • TransPennine Express – Manchester Airport to Edinburgh Waverly – 1 tp2h – Class 397 – Electric
  • TransPennine Express – Manchester Airport to Glasgow Central – 1 tp2h – Class 397 – Electric

Note.

  1. tpd is trains per day.
  2. tph is trains per hour.
  3. tp2h is trains per two hours.
  4. LNER services to Glasgow and Stirling are likely to be dropped.
  5. Some Lumo services are likely to be extended from Edinburgh to Glasgow.
  6. Many services South from Stirling to Edinburgh Waverley and Glasgow Queen Street are electric.

The current two tpd direct trains to Stirling are electric and if you change at Edinburgh Waverley or Glasgow, it is likely to be an all-electric service.

For marketing reasons, I would recommend, that Grand Union Trains ran electric trains between London Euston and Stirling, as they are competing against an all-electric service.

Although to meet service dates it might be necessary to run something like a diesel Class 222 train to get the service started.

What Trains Will Grand Union Use?

The Wikipedia entry for Grand Union Trains, says this for their London Euston and Stirling service.

In 2023 Grand Union revised its proposal changing its planned rolling stock to Class 22x units, at the same time the start date for this service was changed to June 2025.

I would suspect they will put in the order for new electric trains fairly sharpish.

The new trains could be.

  • A variant of Hitachi’s Class 800 trains.
  • A variant of CAF’s Class 397 trains.

Would they have an emergency battery un case of overhead line failure?

How Long Will A Service Take?

The service can be divided into two sections.

  • London Euston and Motherwell – 388 miles.
  • Motherwell and Stirling – 28.9 miles.

Note.

  1. The 08:30 train from Euston to Motherwell takes 4 hours and 17 minutes with six stops via Nuneaton.
  2. The Grand Union Trains service will also have six stops and go via Nuneaton.

I would expect with today’s signalling and electric trains, that Euston and Motherwell would take a maximum of 4 hours and 17 minutes.

  • The twenty minute time to Cumbernauld could be added.
  • The twenty-five minute time between Cumbernauld and Stirling could be added.

It looks the time would be just over five hours.

I doubt there would be much scope for increasing speed North of Motherwell, but could there be savings made to the South of Motherwell?

Consider.

  • London Euston and Motherwell is 388 miles.
  • Four hours and 17 minutes is 257 minutes.
  • Motherwell is on the main London Euston and Glasgow Central route.

This is an average speed between London Euston and Motherwell of 90.6 mph.

By comparison.

  • London King’s Cross and Edinburgh is 392.6 miles.
  • Journeys can take four hours and 20 minutes or 260 minutes.

This is an average speed between London King’s Cross and Edinburgh of 90.6 mph.

In the next decade, there will be improvements on both the East and West Coast Main Lines.

  • King’s Cross and Edinburgh is currently being digitally signalled.
  • London Euston and Glasgow Central is likely to be an early priority for digital signalling after London King’s Cross and Edinburgh is completed.
  • When High Speed Two opens to Birmingham and Lichfield, High Speed Two trains between London Euston and Glasgow Central will use the West Coast Main Line to the North of Lichfield.
  • I wouldn’t be surprised to see some track realignment and modifications to improve speeds on the West Coast Main Line to the North of Lichfield.

I can build a table of times between London Euston and Motherwell against average speed.

  • 90 mph – 4 hours 19 minutes
  • 100 mph – 3 hours 53 minutes
  • 110 mph – 3 hours 32 minutes
  • 120 mph – 3 hours 14 minutes
  • 125 mph – 3 hours 6 minutes
  • 130 mph – 2 hours 59 minutes

Note.

  1. Adding 15 minutes gives a London Euston and Glasgow Central time.
  2. Adding 45 minutes gives a London Euston and Stirling time.
  3. Averaging 120 mph would give London Euston and Glasgow Central or Stirling times of under four hours.

It strikes me, that to improve Anglo-Scottish relations and to make rail a better alternative to flying, a priority for all West Coast services is to improve the West Coast Main Line and install digital signalling, so that a 120 mph average is possible between London Euston and Motherwell.

What Difference Will High Speed Two Make?

High Speed Two is claiming it will knock thirty minutes off times between London Euston and Glasgow Central, when it opens to Birmingham and Lichfield.

But Grand Union Trains are not expected to use the new line between London Euston and Lichfield, as High Speed Two will, as it will make calling at Milton Keynes and Nuneaton impossible, as they are bypassed by High Speed Two.

Conclusion

This train service is going to be good for Milton Keynes, Nuneaton and Stirling and all the towns in Central Scotland.

But they must make full use of the available electrification.

 

 

March 11, 2024 Posted by | Transport/Travel | , , , , , , , , , , , , , , , , , , , , | 3 Comments

Hydrogen Start-Up Can Expand Thanks To Northern Powerhouse Fund

The title of this post, is the same as that of this article in The Times.

This is the sub-heading.

Suiso’s technology for extracting clean fuel has been found to produce lower emissions and use less energy than common alternatives

These three paragraphs describe the finances and outline the their hydrogen generator.

Suiso, a South Yorkshire-based company developing a hydrogen generator, has raised £3 million from the Northern Powerhouse Investment Fund (NPIF).

The company plans to create generators as big as shipping containers that could power factories, hospitals and warehouses or be used at filling stations to fuel hydrogen-powered vehicles.

The new funds come from the asset manager Mercia’s equity finance fund, which is part of the NPIF, and Mercia’s enterprise investment scheme.

This paragraph describes the technology.

Suiso uses novel microwave technology to extract hydrogen from natural gas or biogas, capturing the carbon in the form of carbon black, which can be used to make tyres, batteries and inks. In 2023 the company was one of the winners of a government competition to provide technology to supply hydrogen energy.

These are my thoughts.

Suiso And HiiROC

Suiso are taking a similar route to HiiROC.

  • The base feedstock is natural gas, which is mainly methane or CH4, with four planet-saving hydrogen atoms and a very naughty carbon one.
  • Clever technology is then applied to the methane atoms and the carbon atom doesn’t like it, so they let go of the hydrogen atoms.
  • It is then a matter of physically separating the carbon black from the hydrogen.

The difference between the two processes is that Suiso use microwave technology and HiiROC  use plasma technology.

HiiROC claim their process will work with any hydrocarbon gas from biomethane through off-gas from a chemical plant to natural gas.

So I suspect, that as Suiso says it will work with biomethane, both technologies will work with virtually any hydrocarbon gas.

Uses Of Carbon Black

This Wikipedia entry gives a lot of information on carbon black.

There is a section, which is entitled Common Uses, where this is said.

The most common use (70%) of carbon black is as a pigment and reinforcing phase in automobile tires. Carbon black also helps conduct heat away from the tread and belt area of the tire, reducing thermal damage and increasing tire life. Its low cost makes it a common addition to cathodes and anodes and is considered a safe replacement to lithium metal in lithium-ion batteries. About 20% of world production goes into belts, hoses, and other non-tire rubber goods. The remaining 10% use of carbon black comes from pigment in inks, coatings, and plastics, as well as being used as a conductive additive in lithium-ion batteries.

Carbon black is added to polypropylene because it absorbs ultraviolet radiation, which otherwise causes the material to degrade. Carbon black particles are also employed in some radar absorbent materials, in photocopier and laser printer toner, and in other inks and paints. The high tinting strength and stability of carbon black has also provided use in coloring of resins and films. Carbon black has been used in various applications for electronics. A good conductor of electricity, carbon black is used as a filler mixed in plastics, elastomer, films, adhesives, and paints. It is used as an antistatic additive agent in automobile fuel caps and pipes.

There is another section, which is entitled Use in Lithium-Ion Batteries, where this is said.

Carbon black is a common conductive additive for lithium ion batteries as they have small particle sizes and large specific surface areas (SSA) which allow for the additive to be well distributed throughout the cathode or anode in addition to being cheap and long-lasting. Unlike graphite, which is one of the other common materials used in chargeable batteries, carbon black consists of crystal lattices that are further apart and promotes Li+ intercalation because it allows more pathways for lithium storage.

Carbon black has a low density that allows for a large volume of it to be dispersed so that its conductive effects are applied evenly throughout the battery. Furthermore, its arrangement of randomly distributed graphite-like crystals improves battery stability because of the decrease in the potential barrier of lithium intercalation into graphite, which ultimately affects the performance of cathodes.

Carbon black does seem to be very useful.

Suiso’s Web Site

This is Suiso’s web site.

The page is headed About Us and this is said.

Suiso is a developer of a low energy near zero emission microwave-driven methane cracking process for onsite generation of Hydrogen. 

Hydrogen, the most abundant element in the universe, is rapidly emerging  as a sustainable solution for the decarbonisation of the economy and a key piece of the energy transition picture in UK, Europe and around the world.  

The cost and practical issues with generating and distributing Hydrogen has held back its use in most economies.  Suiso’s technology uses existing electrical, natural/bio gas assets and infrastructure to produce clean low cost hydrogen.  By transforming stranded ‘brown’ assets into vital hydrogen infrastructure, Suiso helps reduce CO2 emissions and enables countries throughout the world to meet challenging greenhouse gas emissions targets, quickly and cost effectively.  

  Suiso’s technology allows its generating units to be positioned anywhere there is a supply of natural/bio gas and electricity. Being located at the point of use eliminates the costly distribution (by truck or pipe) of H2 to the customer – delivering significant cost reductions. This allows it to offer competitively priced H2 for small to medium sized applications in developed and developing countries., including:   

  • H2 Fueling stations
  • Biomethane (H2) conversion/decarbonisation for grid injection
  • Light industrial applications
  • Domestic H2 supply for small communities/towns
  • Demand management/System top up
  • Emergency H2 supply

It will design, build and supply these generators directly or via licensees to markets throughout the world.

Conclusion

I like this company.

March 11, 2024 Posted by | Hydrogen | , , , | Leave a comment

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