The Anonymous Widower

Are LNER Going To Take On The Airlines?

Nine years ago, I wrote Edinburgh – Plane Or Train?, after a trip to Scotland, where I took easyJet up and came back in First Class by train.

  • Both trips were about five hours door-to-door.
  • The flight was about six quid more,
  • But I got free food and drink on the train.
  • Security on the plane was a pain.
  • I had to take my passport for identification at Stansted.

I haven’t flown internally in Great Britain since, although, I have flown to Belfast.

For shorter flights the market is going towards rail, as these posts seem to suggest.

The climate seems to be turning against flying short-haul.

This is a paragraph, in this press release from LNER, which is entitled First Tri-Mode Long Distance Trains For The East Coast Main Line.

This new fleet of trains will keep LNER on track to reduce its emissions by 67 per cent by 2035 and be net zero by 2045. LNER has already reduced carbon emissions by 50 per cent compared with 2018/19. Per mile, LNER trains produce 15 times less carbon emissions than a domestic flight.

Are LNER building a number of climate-based sticks, with which to beat the airlines on the routes, where they compete?

These are my thoughts on the various routes, where LNER compete with airlines.

Newcastle

Newcastle is an interesting one.

  • Newcastle station is in the city centre and is on the Tyne and Wear Metro.
  • London King’s Cross is one of London’s major Underground hubs.
  • There are lots of buses and local trains within walking distance of both stations.
  • There are three trains every two hours and an additional eight trains per day (tpd) between the two London King’s Cross and Newcastle stations.
  • Lumo also run five tpd on the route.
  • There are generally no security delays at rail stations.
  • London King’s Cross is laid out to maximise passenger flows. If it gets busy, everybody just walks out into King’s Cross Square.
  • I’ve never had a problem at Newcastle station with overcrowding.

Perhaps, if you live near one of the airports, flying is more convenient.

LNER’s weapons against the airlines between London King’s Cross and Newcastle will be convenience and journey times.

Convenience is all about the location of the stations, their excellent  local transport networks and good walking routes around the station.

Journey times will only get better, as the magic of digital in-cab signalling, allows the Azumas, the new CAF tri-mode long distance trains and the few remaining InterCity 225s to show what they were designed to do.

Dalton-on-Tees, where the first phase of the digitally signalling will end, is 39.8 miles South of Newcastle, so once the Newcastle train is passes Dalton-on-Tees on the East Coast Main Line, it will be a digital-signalled electrified railway all the way to Woolmer Green.

  • Dalton-on-Tees is 39.8 miles South of Newcastle
  • Woolmer Green is 244.8 miles South of Newcastle.
  • Dalton-on-Tees and Woolmer Green is 205 miles.
  • Newcastle and Dalton-on-Tees takes 37 minutes.
  • Woolmer Green and King’s Cross takes 18 minutes
  • Trains take typically an average three hours and nine minutes between London and Newcastle.
  • A typical train time by LNER between Dalton-on-Tees and Woolmer Green is two hours and 14 minutes.
  • This is an average speed of 91.8 mph between Dalton-on-Tees and Woolmer Green.
  • Between London King’s Cross and Newcastle is fully-electrified.

I can build a table of timings and savings at various average speeds.

  • 120 mph – 103 minutes – two hours and 38 minutes – 31 minutes
  • 125 mph – 98 minutes – two hours and 33 minutes – 36 minutes
  • 130 mph – 95 minutes – two hours and 30 minutes – 39 minutes
  • 135 mph – 91 minutes – two hours and 26 minutes – 43 minutes
  • 140 mph – 88 minutes – two hours and 23 minutes – 46 minutes

Note.

  1. The first field is the average speed between Dalton-on-Tees and Woolmer Green.
  2. The second field is the time between Dalton-on-Tees and Woolmer Green.
  3. The third field is the time between London and Newcastle.
  4. The fourth field is the saving over current timings.
  5. The London and Newcastle time is calculated by adding the times for the three sections together.

I have regularly timed trains at a very constant 125 mph, so with digital signalling, I suspect an average of 130 mph is possible.

This would mean, times of a few minutes under two hours and thirty minutes could be possible between London and Newcastle.

Edinburgh

Edinburgh builds on the improvements South of Newcastle.

Edinburgh station Waverley is a well-connected station.

  • There are lots of buses, local trains and the Edinburgh Tram within walking distance of Edinburgh Waverley station.
  • There are three trains every two hours and an additional seven tpd between the London King’s Cross and Edinburgh Waverley stations.
  • Lumo also run five tpd on the route.
  • Trains take typically an average four hours and thirty minutes between London and Edinburgh Waverley.
  • Any savings because of the digital in-cab signalling between London and Newcastle can be applied to London and Edinburgh Waverley services.

As my calculations showed that averaging 130 mph between Dalton-on-Tees and Woolmer Green could save 39 minutes on journey times, I am fairly sure than a sub-four hour journey time will be possible between London and Edinburgh Waverley.

It should also be noted that that the power supply has been improved between Newcastle and Edinburgh Waverley.

  • The distance between Newcastle and Edinburgh Waverley is 124.2 miles
  • Newcastle and Edinburgh Waverley takes around one hour and 30 minutes.
  • This is an average speed of 82.8 mph between Newcastle and Edinburgh Waverley.
  • Between London King’s Cross and Edinburgh Waverley is fully-electrified.

As the record time for between London King’s Cross and Edinburgh Waverley was set by an InterCity225 train in 1993 at three hours and twenty-nine minutes, I suspect that with more digital signalling and some track improvements, that there are more journey time improvements to be squeezed out.

I certainly believe that a time of three hours and fifty minutes between London and Edinburgh Waverley will be regularly achieved. This is a journey time saving of around forty minutes.

Dundee

Dundee has an airport and a station on the East Coast Main Line.

Trains between London  King’s Cross and Dundee take around five hours and 45 minutes.

LNER run three trains per day to and from London King’s Cross and one tpd to and from Leeds.

CrossCountry also run services.

Loganair has two flights per day to Heathrow.

Aberdeen

Aberdeen builds on the improvements South of Edinburgh.

The four direct tpd between London and Aberdeen take around seven hours and ten minutes.

This should come down to around six hours and thirty minutes with the journey time savings between London King’s Cross and Edinburgh Waverley.

Will this tempt travellers from the airlines?

Battery-Electric Trains To Dundee And Aberdeen

One thing that will help, is that Edinburgh and Aberdeen is to be partially electrified.

InPiling Work To Get Underway To Electrify Line To Fife, I included this Network Rail map of the electrification.

This map has been downloaded from the Network Rail web site.

The electrification is split into four phases.

  1. Haymarket and Dalmeny – 25 km
  2. Kirkcaldy and Thornton North – 25 km.
  3. Lochgelly and Thornton North – 20 km.
  4. Thornton North and Ladybank – 34 km.

Note.

  1. The last three phases of electrification connect to Thornton North.
  2. The new rail link to Leven will also be electrified. and connected to Thornton North.
  3. The Forth Bridge is not to be electrified.

As Ladybank station is just 91.4 miles from Aberdeen, I suspect LNER will use  Hitachi Intercity Battery Hybrid Trains to serve Aberdeen.

If these trains haven’t got the range, then I suspect LNER’s new CAF Tri-Mode Trains could handle the route.

Inverness

Inverness has a problem.

Zero-carbon trains will be unlikely to get to the city without  full electrification of the Highland Main Line.

  • Dunblane is the nearest electrified station to Inverness, but it is 146.2 miles away over a route with lots of steep climbs.
  • I doubt that a battery-electric train could handle that route.

One solution would be for LNER to run the new CAF Tri-Mode Trains to Inverness using HVO or biodiesel.

Glasgow

Glasgow is the only other Scottish city with an airport and good rail connections to the South.

I am sure that Avanti West Coast will target airline passengers, if LNER prove it is a successful policy.

Other Factors

These are other factors, that will come into a traveller’s choice.

First Class

Some travellers like a bit more comfort and service.

Ability To Work

Some travellers like to work on a train.

You Don’t Get Tables On a Plane

I like to open a paper or magazine flat, which is difficult on a plane.

Views Tend To Be Better On a Train

Providing you get a window!

Parking Tends To Be Better At An Airport

But it may be more expensive!

Security Is Less Hassle On A Train

At the moment!

You Don’t Need To Prove Your Identity On A Train

Not in the UK! Yet!

Conclusion

It looks like LNER can offer the airlines to four of our major Northern cities serious zero-carbon competition.

 

November 19, 2023 Posted by | Transport/Travel | , , , , , , , , , , , , , , , , , , , , , , , , , , | 2 Comments

Could The New Northumberland Line Be Used As A Diversion For The East Coast Main Line?

This question was asked by a friend, so I thought I’d investigate.

This OpenRailwayMap shows the Southern end of the Northumberland Line.

Note.

  1. Tracks in red are the 25 KVAC overhead electrified East Coast Main Line.
  2. Tracks in blue are the 1.5 kV overhead electrified Tyne and Wear Metro.
  3. The track in black running alongside the Metro and then turning North is the Northumberland Line.
  4. The Northumberland Line is mainly double track, with some single-track sections.
  5. The blue arrow indicates Northumberland Park station.

At Benton Junction junction in the South-West corner of the map, trains can be handled in the following directions.

  • Trains going North on the East Coast Main Line can go North on the Northumberland Line.
  • Trains going South on the Northumberland Line can go South on the East Coast Main Line.

Currently, only the occasional freight train uses the junction.

When the Northumberland Line opens, there will be two trains per hour (tph) in each direction.

This second OpenRailwayMap shows the Northern end of the Northumberland Line.

Note.

  1. Tracks in red are the 25 KVAC overhead electrified East Coast Main Line.
  2. The blue arrow indicates the Ashington station, which will be the Northern terminus of Northumberland Line services.
  3. The Northumberland Line runs down the Eastern side of the map.
  4. The village of Bedlington, which will have a station on the Northumberland Line is in the South-East corner of the map.
  5. A second track connects Bedlington on the Northumberland Line to the East Coast Main Line, where trains can go North or South.

It does appear that because of the track layout at both ends of the Northumberland Line, the following is possible.

A train going in either direction on the East Coast Main Line can use the Northumberland Line as a diversion.

Passenger services between Newcastle and Morpeth could use the Northumberland Line.

Passenger services between Newcastle and North of Morpeth could use the Northumberland Line.

Note.

  1. Although High Speed Two through Newcastle is probably dead, there is still a need to increase capacity through the area.
  2. I suspect diversions could be useful, when there were problems between Newcastle and Morpeth.
  3. Could the Northumberland Line be used for freight trains to increase capacity through Newcastle?
  4. We shouldn’t ignored the possibilities offered by a reopened Leamside Line.

But I suspect that as housing and other developments get proposed in Northumberland, that more passenger services will be developed.

Conclusion

The Northumberland Line will have limited use for diversions, but could general other services.

November 16, 2023 Posted by | Transport/Travel | , , , , , , , , , | Leave a comment

The Data Sheet For Hitachi Battery Electric Trains

Was I just slow to spot this data sheet or has it only just been released?

You can download a copy from this page on the Hitachi web site.

In a section on the page, which is entitled Intercity Battery Trains, this is said.

A quick and easy application of battery technology is to install it on existing or future Hitachi intercity trains. Adding just one battery reduces emissions by more than 20% and offers cost savings of 20-30%.

Our intercity battery powered trains can cover 70km on non-electrified routes, operating at intercity speeds at the same or increased performance. Hitachi Rail’s modular design means this can be done without the need to re-engineer or rebuild the train and return them to service as quickly as possible for passengers.

These are my initial thoughts.

Plug-and-Play

It looks like the train is plug-and-play.

A diesel engine will be swapped for a battery-pack and the train’s computer controls the power sources accordingly.

Hitachi’s Battery Philosophy Explained

This is said on the data sheet.

Battery technology has the potential to play a significant role in the future of sustainable rail mobility, setting
the rail industry on the path to full intercity decarbonisation by 2050.
Installing batteries on intercity trains can complement electrification and provide a low emission alternative
to domestic air travel.

Our retrofit solution for intercity trains offers phased replacement of diesel engines at the time that they would
have been due for their regular heavy maintenance overhaul, replacing each engine in turn until trains are fully battery electric. The solution delivers fuel cost savings and lowers CO2 emissions by at least 20% for every engine replaced, and a 20% reduction in whole life maintenance costs – well within the battery’s life span of 8-10 years.

Performance On Battery Power

The data sheet gives these bullet points.

  • 750kW peak power
  • Weight neutral.
  • At least 20% lower CO2 emissions
  • 70km on non-electrified routes
  • 20% reduction in whole life maintenance costs
  • Up to 30% fuel cost savings
  • Zero emissions in and out of stations
  • Charge on the move
  • 10 year life span

Note.

  1. 750 kW peak power, is around the power of the diesel-engine, that will be replaced.
  2. I wouldn’t be surprised that powerwise, the battery pack looks like a diesel engine.
  3. Weight neutral means that acceleration, performance and handling will be unchanged.
  4. Batteries are easier to maintain than diesels.
  5. It is stated that a train can be fully-decarbonised.

I have a feeling these trains are no ordinary battery-electric trains.

Seventy Kilometre Range On Battery

Seventy kilometres is 43.5 miles.

This may not seem much, but the data sheet says this.

Our battery hybrid trains can cover 70km on non-electrified routes, operating at intercity speeds at the same
or increased performance. By identifying the routes with short non-electrified sections of 70km or less, we could
see the replacement of existing diesel trains with fully battery-operated trains on those routes within a year.
And, using battery power to avoid electrifying the hardest and most expensive areas, such as tunnels and bridges,
enables flexibility on electrification, minimising passenger disruption during upgrades.

Note.

  1. It looks like the trains can operate at 125 mph on battery power, where the track allows it. But then the rolling restistance of steel wheel on steel rail, is much lower, than that of rubber tyres on tarmac.
  2. Hitachi seem to have developed a philosophy on how the trains will be used.
  3. Hitachi’s pantographs, go up and down with all the alacrity of a whore’s drawers. They will be ideal for a short length of electrification.

I think these LNER routes could be immediately decarbonised.

  • LNER – London and Harrogate , where only 18.3 miles is unelectrified. Trains may not need charging, as a full battery could handle both ways.
  • LNER – London and Hull, where 36.1 miles is unelectrified. A short length of electrification to charge trains would be needed at Hull.
  • LNER – London and Lincoln, where only 16.7 miles is unelectrified. Trains would not need charging, as a full battery could handle both ways.
  • LNER – London and Middlesbrough, where only 20.3 miles is unelectrified. Trains would not need charging, as a full battery could handle both ways.

Note.

  1. It looks like some services could start fairly soon, once batteries are available.
  2. Hull Trains could use the 70 km batteries and charging at Hull, as it passed through. This would decarbonise Hull Trains passenger operations.
  3. Services to Aberdeen, Cleethorpes and Inverness would be out of range of the initial Hitachi trains.

Could the last point, partially explain the purchase of the CAF tri-mode trains, which I wrote about in First Tri-Mode Long Distance Trains For The East Coast Main Line?

We shall see what we shall see.

But having a choice of battery-electric or tri-mode trains will enable route development and decarbonisation.

What Is The Size Of The Battery Pack?

In How Much Power Is Needed To Run A Train At 125 Or 100 mph?, I estimated that to maintain 125 mph, a Class 801 train has a usage figure of 3.42 kWh per vehicle mile.

If a five-car Class 800 can run 70 km or 43.5 miles at 125 mph, as indicated by Hitachi, then the battery size can be calculated.

3.42 * 5 * 43.5 = 743.85 kWh

As the battery pack can supply 750 kW according to the data sheet, this looks like this will run the train for an hour.

Is that coincidence or a design criteria?

What Battery Capacity Would Be Needed For A Hundred Miles?

For a five-car train, this is the energy needed for a hundred miles.

3.42 *5 * 100 = 1710 kWh or three batteries.

For a nine-car train, this is the energy needed for a hundred miles.

3.42 *9 * 100 = 3078 kWh or five batteries.

It looks like all diesel engines will be replaced by batteries.

Will Class 801 Trains Swap Their Single Diesel Engine For a Battery Power Pack?

Consider.

  • Class 801 trains have a single diesel engine for emergency power.
  • Lumo’s Class 803 trains, are all-electric with a battery-pack for emergency hotel power only.
  • Hitachi must have full details on the performance of Lumo’s trains.
  • The East Coast Main Line is notorious for the wires to come tumbling down.
  • The diesel engine and the battery pack appear to weigh the same.
  • Batteries cost less to maintain than diesels.

I can’t see why the single diesel engine can’t be replaced by a standard battery pack, without loosing any functionality.

What Would Be The Range Of A Fully Battery-Electric Train?

This is a paragraph from a data sheet.

Our retrofit solution for intercity trains offers phased replacement of diesel engines at the time that they would
have been due for their regular heavy maintenance overhaul, replacing each engine in turn until trains are fully battery electric. The solution delivers fuel cost savings and lowers CO2 emissions by at least 20% for every engine replaced, and a 20% reduction in whole life maintenance costs – well within the battery’s life span of 8-10 years.

Note.

  1. It looks like Hitachi are expecting operators to replace engines in turn.
  2. Replacing engines with batteries saves the operators money.

As a five-car Class 800 train has three diesel engines and a nine-car train has five engines, does this mean that the range of fully-batteried Class 800 train is 70 km or 210 km?

  • A fully-batteried Class 800 train will weigh the same as the current diesel.
  • One battery can drive the train for 70 km at 125 mph according to Hitachi.
  • There are no branches of electrified lines that are 125 mph lines without electrification.
  • I would assume that the train can use regenerative braking to recharge the batteries.
  • 210 kilometres is 130 miles.

I don’t know much about the electrical systems of Hitachi’s trains, but it is likely that there will be an electrical bus to distribute power from one end of the train to the other.

So a five-car Class 800 train with three fully-charged battery packs could have over 2 MWh of electricity on board, that could be used for traction.

  • Applying the usage figure of 3.42 kWh per vehicle mile, gives a range for the five-car train of at least 117 miles.
  • The equivalent figure for a nine-car train will be at least 121 miles.

These distances would open up routes like these on the East Coast Main Line.

  • LNER – London King’s Cross and Aberdeen – 91.4 miles – Charge before return.
  • LNER/Hull Trains – London King’s Cross and Beverley via Temple Hirst junction – 44.3 miles – No Charging needed before return.
  • Grand Central – London King’s Cross and Bradford Interchange via Shaftholme junction – 47.8 miles – No Charging needed before return.
  • LNER – London King’s Cross and Cleethorpes via Newark and Lincoln – 63.9 miles – Charge before return.
  • LNER – London King’s Cross and Harrogate via Leeds – 18.3 miles – No Charging needed before return.
  • LNER – London King’s Cross and Inverness– 146.2 miles – Charge before return.
  • LNER/Hull Trains – London King’s Cross and Hull via Temple Hirst junction – 36.1 miles – No Charging needed before return.
  • LNER – London King’s Cross and Middlesbrough via Northallerton – 20.3 miles – No Charging needed before return.
  • LNER – London King’s Cross and Scarborough via York – 42.1 miles – No Charging needed before return.
  • LNER/Grand Central – London King’s Cross and Sunderland via Northallerton – 47.4 miles – No Charging needed before return.

Note.

  1. The miles are the longest continuous distance without electrification.
  2. Only Aberdeen, Cleethorpes and Inverness would need to charge trains before return.
  3. Inverness may be too far. But is it in range of LNER’s new CAF tri-mode trains?

The battery range  would also allow LNER to use the Lincoln diversion on the Joint Line.

Why Didn’t LNER Buy More Azumas?

This puzzles me and I suspect it puzzles other people too.

Surely, an all Azuma fleet will be easier to manage.

But in this article on Modern Railways, which is entitled LNER Orders CAF Tri-mode Sets, this is said.

Modern Railways understands the new fleet will be maintained at Neville Hill depot in Leeds and, like the ‘225’ sets, will be used predominantly on services between London and Yorkshire, although unlike the ‘225s’ the tri-modes, with their self-power capability, will be able to serve destinations away from the electrified network such as Harrogate and Hull.

Note.

  1. Hull would possibly need work to provide some form of charging for battery-electric Azumas, but Harrogate is close enough to be served by a one-battery Azuma.
  2. The CAF Tri-mode sets would certainly handle routes like Cleethorpes, Middlesbrough and Sunderland, but would they really need a ten-car train.
  3. Ten-car trains would also be busy on the Leeds route.
  4. The UK is going to need more 125 mph trains for Cross Country, Grand Central, Grand Union, TransPennine Express and possibly other train companies.
  5. Has Hitachi got the capacity to build the trains in the UK?

So has the Government given the order to CAF to create a level of competition?

Conclusions

These are my conclusions about Hitachi’s battery packs for Class 80x trains, which were written in November 2023.

  • The battery pack has a capacity of 750 kWh.
  • A five-car train needs three battery-packs to travel 100 miles.
  • A nine-car train needs five battery-packs to travel 100 miles.
  • The maximum range of a five-car train with three batteries is 117 miles.
  • The maximum range of a nine-car train with five batteries is 121 miles.

As battery technology gets better, these distances will increase.

Hitachi have seen my figures.

They also told me, that they were in line with their figures, but new and better batteries would increase range.

In July 2025, I wrote Batteries Ordered For Grand Central Inter-City Trains, which mentions the following.

  • Grand Central’s trains will be electric-diesel-battery hybrid inter-city trainsets.
  • The trains will have lithium ion phosphate batteries.
  • The trains will be delivered in 2028.
  • The batteries will be smaller and more powerful, than current batteries.

This is also said about safety, hazards and cybersecurity.

The Safety Integrity Level 2 and IEC 61508 compliant battery management system will detect and mitigate hazards and meet the IEC 62243 cybersecurity standard.

These batteries would appear to give Hitachi and Grand Central Trains everything they want and need.

It looks like the new battery chemistry, will give Hitachi extra range.

November 14, 2023 Posted by | Transport/Travel | , , , , , , , , , , , , , , | 14 Comments

Grand Central Trains And CAF’s Tri-Mode Trains

In First Tri-Mode Long Distance Trains For The East Coast Main Line, I wrote about LNER’s purchase of a new fleet of ten CAF tri-mode trains to work services between London and Yorkshire.

In this press release from LNER, which is entitled First Tri-Mode Long Distance Trains For The East Coast Main Line, this is a paragraph.

This new fleet of trains will keep LNER on track to reduce its emissions by 67 per cent by 2035 and be net zero by 2045. LNER has already reduced carbon emissions by 50 per cent compared with 2018/19. Per mile, LNER trains produce 15 times less carbon emissions than a domestic flight.

I believe that as they compete over similar routes with LNER, that Grand Central Trains will have to implement a similar decarbonisation strategy or their business will suffer.

The new trains for Grand Central Trains, will need to have the following conditions.

Train Length

Consider.

  • The train must be able to fit all the platforms it will use.
  • Ten-cars may be too long for some of the platforms.
  • Train length should also be long enough to capture as much of the market as possible.

But as adjusting the length of trains is an easy process, I suspect all manufacturers will be happy to supply extra carriages.

Distances Without Electrification

These are the distances on Grand Central Trains’s services without electrification.

  • Doncaster and Bradford Interchange – 52.1 miles
  • Northallerton and Sunderland – 47.4 miles

A battery-electric train with a battery range of 110 miles would probably be able to reach Sunderland and return, after charging on the main line.

But a CAF tri-mode train, which ran on diesel or a suitable sustainable fuel like biodiesel or HVO wouldn’t give the driver, operator or passengers any worries.

Possible Time Savings To Bradford

Digital signalling is being installed on the East Coast Main Line between Woolmer Green and Dalton-on-Tees, which will allow running on the line up to 140 mph.

  • Woolmer Green is 132.1 miles South of Doncaster.
  • A typical train time by Grand Central Trains is 75 minutes.
  • This is an average speed of 110 mph.
  • Trains take typically three hours and eight minutes between London and Bradford Interchange.

I can build a table of timings and savings at various average speeds.

  • 120 mph – 66 minutes – 9 minutes
  • 125 mph – 63 minutes – 12 minutes
  • 130 mph – 61 minutes – 14 minutes
  • 140 mph – 57 minutes – 18 minutes

Several times, I have timed an Hitachi train running at 125 mph on routes like the East Coast Main Line, Great Western Main Line, Midland Main Line and West Coast Main Line, so I have no doubt, that London and Bradford Interchange services can be less than three hours.

These journey time savings will be available to any train able to use the digital electrified railway to the South of Doncaster.

Possible Time Savings To Sunderland

Dalton-on-Tees, where the first phase of the digitally signalling will end, is North of Northallerton, so once the Sunderland train is on the East Coast Main Line, it will be a digital electrified railway all the way to Woolmer Green.

  • Woolmer Green is 194.6 miles South of Northallerton.
  • A typical train time by Grand Central Trains is 151 minutes.
  • This is an average speed of 77.3 mph.
  • Trains take typically three hours and twenty-eight minutes between London and Sunderland.

I can build a table of timings and savings at various average speeds.

  • 120 mph – 97 minutes – 54 minutes
  • 125 mph – 93 minutes – 58 minutes
  • 130 mph – 89 minutes – 62 minutes
  • 140 mph – 83 minutes – 68 minutes

It looks like times of two hours and thirty minutes will be possible between between London and Sunderland.

Will The Trains Need A 140 mph Capability?

Trains will need to average 125 mph on the digital electrified East Coast Main Line to get under three hours for Bradford Interchange and 2½ hours for Sunderland, so I feel a 140 mph capability is required between Northallerton and London.

Could The Trains Split And Join At Doncaster?

High speed paths on the digitally signalled and electrified East Coast Main Line might be at a premium, so running pairs of five-car trains to two destinations could be commonplace working.

  • It could be a way of increasing frequency to Bradford Interchange and Sunderland, by perhaps running pairs of five-car trains that split at Doncaster.
  • Grand Union Trains have proposed in the past to use splitting and joining to run services to Cleethorpes.

As Hitachi trains can split and join, I suspect that the CAF tri-mode trains will be at least able to be retrofitted with the ability.

Conclusion

These are my conclusions.

  • The digital signalling certainly gives good time saving to Yorkshire and the North-East
  • New trains for Grand Union Trains would give them faster services on their existing routes.
  • Trains with a 140 mph capability would be needed.
  • CAF tri-mode trains wouldn’t need any new infrastructure, but battery-electric trains may need chargers at the destinations.
  • Because of the lower infrastructure requirements, I think the CAF trains will get the nod.

 

November 12, 2023 Posted by | Transport/Travel | , , , , , , | 6 Comments

First Tri-Mode Long Distance Trains For The East Coast Main Line

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

This is the sub-heading.

London North Eastern Railway (LNER) is pleased to confirm that CAF has been named as the successful bidder to deliver a fleet of 10 new tri-mode trains for LNER. Porterbrook has been chosen as the financier of the new fleet. The trains will be able to operate in electric, battery or diesel mode.

These are the first two paragraphs.

Benefits of tri-mode trains range from a reduction in emissions, particulates, noise and vibration pollution, lower maintenance and operating costs and upgradeable technology, with an expected increase in range and performance as technology develops further. Battery power reduces the need to use diesel traction in areas where overhead powerlines are not available.

Complementing the modern Azuma fleet of 65 trains, the new ten-coach trains will help LNER achieve its vision of becoming the most loved, progressive and trusted train operator in the UK, delivering an exceptional service for the customers and communities served along its 956-mile network.

I have a few thoughts.

Will The Trains Have Rolls-Royce mtu Diesel Engines?

Consider.

  • CAF’s Class 195, 196 and 197 Civity trains for the UK all have Rolls-Royce mtu diesel engines.
  • Porterbrook are headquartered in Derby.
  • Rolls-Royce are headquartered in Derby.
  • In Rolls-Royce And Porterbrook Agreement Will Drive Rail Decarbonisation, I talked about how the two companies were planning to  decarbonise trains using techniques like mtu Hybrid PowerPacks and hydrogen fuel cells.

I would think it very likely that the new trains will have Rolls-Royce mtu engines.

Will The Trains Have Rolls-Royce mtu Hybrid PowerPacks?

It was in 2018, that I first wrote about mtu Hybrid PowerPacks in Rolls-Royce And Porterbrook Launch First Hybrid Rail Project In The UK With MTU Hybrid PowerPacks.

  • Examples of these power packs are now running in Germany, Ireland and the UK.
  • The mtu Hybrid PowerPack how has its own web site.
  • There is also this YouTube video.
  • If CAF use off-the-shelf mtu Hybrid PowerPacks in their Civity trains, there is one big massive plus – They don’t have to develop the complicated control software to get a combination of diesel engines and batteries to perform as immaculately as Busby Berkeley’s dancers or a Brigade of Guards.
  • The mtu Hybrid PowerPacks also have a big plus for operators – The batteries don’t need separate charging infrastructure.
  • In Rolls-Royce Releases mtu Rail Engines For Sustainable Fuels, I talk about how mtu engines can run on sustainable fuels, such as biodiesel or HVO.

I think it is extremely likely that CAF’s new trains for LNER will be powered by mtu Hybrid PowerPacks.

Class 800 And Class 397 Trains Compared

The Class 800 train is LNER’s workhorse to Scotland from London.

The Class 397 train used by TransPennine Express, is a 125 mph Civity train.

Differences include.

  • The Class 800 train can run at 140 mph, where the signalling allows, but is the Class 397 train only capable of 125 mph?
  • The Class 397 train accelerate at 0.92 m/s², whereas the Class 800 train can only manage 0.7 m/s².
  • The Hitachi train has 14 % more seats, 36 First and 290 Standard as opposed to 22 First and 264 Standard in five-car trains.

I will add to this list.

Will The New Trains Be Capable Of 140 mph Running?

As the East Coast Main Line is being fully digitally signalled to  allow 140 mph running of the numerous Hitachi expresses on the route, I wouldn’t be surprised to see, that the new CAF trains will be capable of 140 mph.

In this article on Modern Railways, which is entitled LNER Orders CAF Tri-mode Sets, this is said.

The new fleet will be equipped with CAF Signalling’s European Rail Traffic Management System digital signalling. This will align with the East Coast Digital Programme, which aims to introduce European Train Control System (ETCS) on the southern stretch of the East Coast main line from King’s Cross to Stoke Tunnel by 2029.

Later in the article this is said.

LNER has retained 12 ‘91s’ hauling eight rakes of Mk 4s, and the rollout of ETCS is another reason the operator has sought to order the replacement fleet. LNER’s passenger numbers have rebounded more quickly than other operators post-Covid, which has helped make the case for confirming the order.

This does seem sensible.

What Will Be The Range Of The CAF Trains Without Electrification?

The longest LNER route without electrification is the Northern section of the Inverness service between Inverness and Dunblane, which is 146.1 miles. There are also eight stops and some hills.

In Edinburgh to Inverness in the Cab of an HST, there’s a video of the route.

I’m sure that even, if they don’t normally run the new trains to Inverness, being able to do so, could be useful at some point.

It should be noted that the Guinness World Record for battery-electric trains is 139 miles, which is held by a Stadler Akku.

I am left with the conclusion that London and Inverness needs a tri-mode train or lots of electrification. Did this rule out Hitachi?

The Number Of Trains Ordered

The Modern Railways article says this about the number of trains.

The contract includes an eight-year maintenance services agreement with an option to extend; CAF says the order value, including maintenance, exceeds €500 million. When the tender was published the intention was to include an option for five additional sets; LNER confirmed to Modern Railways there is an option to purchase additional sets on top of the base order of 10.

Can we assume this means that other trains will be ordered, if the trains are a success?

Can These New CAF Trains Be Made Net Zero?

This is a paragraph, in the LNER press release.

This new fleet of trains will keep LNER on track to reduce its emissions by 67 per cent by 2035 and be net zero by 2045. LNER has already reduced carbon emissions by 50 per cent compared with 2018/19. Per mile, LNER trains produce 15 times less carbon emissions than a domestic flight.

As the new CAF trains will probably have a service life of at least forty years, there must be some way, that these new trains can be made net zero.

Consider.

  • I am absolutely certain, that the new CAF trains will have Rolls-Royce mtu diesel engines.
  • LNER’s existing Class 800 and 801 trains have Rolls-Royce mtu diesel engines.

Rolls-Royce mtu according to some of Rolls-Royce’s press releases appear to be developing net zero solutions based on hydrogen or net zero fuels.

This press release from Rolls-Royce is entitled Rolls-Royce Successfully Tests mtu Engines With Pure Hydrogen, suggests that Rolls-Royce mtu are working on a solution.

Routes They Will Serve

The Modern Railways article says this about the routes to be served.

Modern Railways understands the new fleet will be maintained at Neville Hill depot in Leeds and, like the ‘225’ sets, will be used predominantly on services between London and Yorkshire, although unlike the ‘225s’ the tri-modes, with their self-power capability, will be able to serve destinations away from the electrified network such as Harrogate and Hull.

Note.

  1. This surprised me, as I’d always expected the Yorkshire routes will be served by Hitachi battery-electric trains.
  2. But it does look that both Harrogate and Hull stations, have long enough platforms to hold a ten-car train.
  3. With their tri-mode technology, it also looks like the CAF trains won’t be needed to be charged before returning to London.

The last point would enable them to try out new routes.

These are distances from the electrification of the East Coast Main Line of the destinations that LNER served, where there is not full electrification.

  • Aberdeen via Ladybank – 91.4 miles
  • Carlisle via Skipton – 86.8 miles
  • Cleethorpes via Newark and Lincoln – 63.9 miles
  • Harrogate via Leeds – 18.3 miles
  • Huddersfield via Leeds – 17.2 miles
  • Hull via Temple Hirst junction – 36.1 miles
  • Inverness via Dunblane – 146.1 miles
  • Lincoln via Newark – 16.7 miles
  • Middlesbrough via Northallerton – 22.2 miles
  • Scarborough via York – 42.1 miles
  • Sunderland via Northallerton – 47.4 miles

Note.

  1. The first place after the ‘via’ is where the electrification ends.
  2. Carlisle could be a possibility during High Speed Two upgrading of the West Coast Main Line or for an enthusiasts’ special or tourist train.
  3. Cleethorpes is a possible new service for LNER. I wrote about this in LNER To Serve Cleethorpes.
  4. Scarborough must be a possible new service for LNER.
  5. All stations can take ten-car trains, with the possible exception of Middlesbrough, which is currently being upgraded.
  6. Huddersfield and Leeds is being electrified under the TransPennine Upgrade.

This would appear to show that LNER need enough bi-mode or tri-mode trains to run services to Aberdeen, Cleethorpes, Harrogate, Hull, Inverness, Lincoln, Middlesbrough and Sunderland.

But.

  • It would appear that the initial batch of trains, will not be serving the North of Scotland.
  • Aberdeen and Inverness could be served, when there is enough electrification at the Southern end.

I am also fairly sure, that no significant infrastructure is required.

Do Hitachi Have A Problem?

I am starting to wonder, if Hitachi are having trouble with the designing and building of their battery packs.

  • It’s not like Hitachi to allow someone to run off with a €500 million contract from under their nose.
  • Are they short of capacity to build the trains at Newton Aycliffe?

But then they’re probably up to their elbows in work on the High Speed Two Classic-Compatible trains.

Are There Any Other Routes, Where The New CAF  Trains Could Be Employed?

The trains would certainly be suitable for these routes.

  • Chiltern – InterCity services.
  • CrossCountry Trains – Fleet replacement
  • Grand Central Trains – Fleet replacement
  • Grand Union Trains – For Carmarthen and Stirling open access services.
  • Great Western Railway – Replacing Castles in the South West.
  • ScotRail – Replacing Inter7City trains.
  • South Western Railway – Basingstoke and Exeter St. Davids and other routes.

Note.

  1. CAF could sell a lot of trains.
  2. I estimate that fleet replacement for Grand Central Trans would cost around €350 million
  3. The specification would vary according to the route.

Could CAF  have got the LNER order, because they have the capacity in the Newport factory?

Conclusion

It looks like CAF have done a good job in designing the trains.

I’m also fairly sure that CAF are using Rolls-Royce mtu PowerPacks.

 

 

 

 

November 11, 2023 Posted by | Transport/Travel | , , , , , , , , , , , , , , , , , , , , , , , , , , , , | 6 Comments

May The Maths Be With You!

It was a bit of a surprise, when in the November 2023 Edition of Modern Railways, in an article, which was entitled Extra Luggage Racks For Lumo, I read this closing paragraph.

Lumo celebrated its second birthday in late October and was also set to mark the carriage of its two-millionth passenger. It is understood Lumo is interested in augmenting its fleet, such has been the success of the service; while many operators favour bi-mode units, Lumo is proud of its all-electric credentials so straight EMUs are still preferred, although the possibilities of including batteries which could power the trains may be pursued (the ‘803s’ have on-board batteries, but only to provide power to on-board systems if the electricity supply fails).

I find this development very interesting.

Surely the obvious way to increase capacity would be to acquire some  extra identical trains and run the busiest services as ten-car trains. I talked about Hull Trains running ten-car trains in Ten-Car Hull Trains. Both companies have five trains, so I suspect that this number would allow for occasional ten-car trains.

If not, then add a few identical trains to the fleet, so capacity can be matched to the demand.

  • Some services would be ten-car instead of five-car.
  • Platforms at Edinburgh, King’s Cross and Newcastle already handle nine and ten-car trains, so infrastructure costs would be minimal.
  • No extra paths would be needed, as a ten-car train can run in a path, that normally has five-car trains, as Hull Trains have shown.

A simple spreadsheet should probably predict, when and how many extra trains need to be added to the fleet.

Lumo And Traction Batteries

But why does the Modern Railways’s article talk about traction batteries?

In the two years since Lumo started their service, there have been days, when the East Coast Main Line has been closed for engineering works, bad weather or an incident. I wrote about an incident in Azumas Everywhere!.

Some of these engineering works have been able to be by-passed by using diversions. But not all of these diversion routes are fully-electrified, so are not available for Lumo.

There would appear to be three viable diversions for the East Coast Main Line.

  • Werrington Junction and Doncaster via Lincoln – Not Electrified – 85.4 miles
  • Doncaster and York via Leeds – Being Electrified – 55.5 miles
  • Northallerton and Newcastle – Not Electrified – 56.8 miles

If all or some of Lumo’s five-car trains had a battery-range of a hundred miles, they would be able to divert around some blockades.

Note.

  1. A traction battery could also provide power to on-board systems if the electricity supply fails.
  2. A traction battery would allow the train to skip past some catenary problems.
  3. I would be interested to know how much diversions, bad weather and incidents have cost Lumo in lost sales and refunds.

As an electrical engineer, I believe, that the emergency-only and the traction batteries could be the same design, but with different software and capacity.

The extra cost of the larger capacity traction battery, might deliver a better service and also pay for itself in the long term.

Extending Lumo’s Route

Lumo will want to maximise revenue and profits, so would it be possible to extend the route North of Edinburgh?

Consider.

  • Edinburgh and Aberdeen is 131.4 miles
  • Ladybank is a station to the North of the Forth Bridge, which is under 40 miles from Edinburgh.
  • The line between Edinburgh and Ladybank is being electrified.
  • Ladybank is just 91.4 miles South of Aberdeen.

At some point in the next few years, I believe that one of Lumo’s trains fitted with a hundred mile traction battery could reach Aberdeen on electric power.

The train would need to be charged at Aberdeen before returning South.

How would Aberdonians like that?

Unfortunately, Inverness is 146.1 miles from the nearest electrification at Dunblane, so it is probably too far for a hundred mile traction battery.

It does appear to me that if Lumo’s trains were fitted with a hundred mile traction battery, this would enable them to take some non-electrified diversions and provide a service to Aberdeen.

How Useful Would A Hundred Mile Range Battery-Electric Train Be To Other Operators?

I take each operator in turn.

Hull Trains

Consider.

  • It appears that Hull Trains change between diesel and electric power at Temple Hirst junction, which is between Doncaster and Selby, on their route between King’s Cross and Hull/Beverley.
  • The distance between Temple Hirst junction and Beverley is 44.3 miles.
  • It would appear that an out-and-return journey could be possible on a hundred mile traction battery.
  • The hundred mile traction battery would also allow Hull Trains to use the Lincoln diversion, either when necessary or by design.

To ensure enough range, a short length of overhead electrification could be erected at Hull station to combat range anxiety.

The Modern Railways article also says this.

The co-operation between sister East Coast Main Line open access operators Lumo and Hull Trains continues, with one recent move being the use of Hull Trains ‘802’ on Lumo services to cover for a shortage of the dedicated ‘803s’ while one was out of action for repairs following a fatality. although the two types are similar, there are notable differences, most obviously that the Hull Trains units are bi-modes while the Lumo sets are straight EMUs, and a training conversion course is required for Lumo drivers on the ‘802s’. There are also challenges from a passenger-facing perspective – the Hull trains units have around 20 % fewer seats and a First Class area.

If Hull Trains used traction batteries rather than diesel engines could the trains be identical to Lumo’s trains from the driver’s perspective?

This would surely appeal to First Group, who are the owner of both Hull Trains and Lumo.

TransPennine Express

These are TransPennine Express services.

  • Liverpool Lime Street and Newcastle – Fully Electrified
  • Liverpool Lime Street and Hull – Part Electrified – Hull and Micklefield – 42 miles
  • Manchester Airport and Saltburn – Part Electrified – Saltburn and Northallerton – 33.6 miles
  • Manchester Piccadilly and Newcastle – Fully Electrified
  • Manchester Piccadilly and Scarborough – Part Electrified – York and Scarborough – 42.1 miles
  • York and Scarborough – Not Electrified – 42.1 miles
  • Manchester Piccadilly and Huddersfield – Fully Electrified
  • Huddersfield and Leeds – Fully Electrified
  • Liverpool Lime Street and Cleethorpes – Part Electrified – Hazel Grove and Cleethorpes – 104.6 miles

Note.

  1. I am assuming that the TransPennine Upgrade has been completed and Manchester and Leeds is electrified.
  2. Liverpool Lime Street and Cleethorpes will need some form of charging at Cleethorpes and a slightly larger battery.

All of these TransPennine  Rxpress routes would be possible with a battery-electric train with a hundred mile traction battery.

LNER

These are distances from the electrification of the East Coast Main Line.

  • Aberdeen via Ladybank – 91.4 miles – Charge before return
  • Bradford Forster Square – Electrified
  • Carlisle via Skipton – 86.8 miles – Charge before return
  • Cleethorpes via Newark and Lincoln – 63.9 miles – Charge before return
  • Harrogate via Leeds – 18.3 miles
  • Huddersfield via Leeds – 17.2 miles
  • Hull via Temple Hirst junction – 36.1 miles
  • Lincoln via Newark – 16.7 miles
  • Middlesbrough via Northallerton – 22.2 miles
  • Scarborough via York – 42.1 miles
  • Skipton – Electrified
  • Sunderland via Northallerton – 47.4 miles

Note.

  1. The first place after the ‘via’ is where the electrification ends.
  2. Carlisle could be a possibility during High Speed Two upgrading of the West Coast Main Line or for an enthusiasts’ special or tourist train.
  3. Cleethorpes is a possible new service for LNER. I wrote about this in LNER To Serve Cleethorpes.
  4. Scarborough must be a possible new service for LNER.
  5. ‘Charge before return’ means the train must be charged before return. Carlisle is electrified, but Cleethorpes is not.
  6. The only new infrastructure would be the charging at Cleethorpes.

All of these LNER routes would be possible with a battery-electric train with a hundred mile traction battery.

The hundred mile traction battery would also allow LNER to use the Lincoln diversion.

Grand Central

These are distances from the electrification of the East Coast Main Line for Grand Central’s services.

  • Bradford Interchange via Shaftholme junction – 47.8 miles
  • Cleethorpes via Doncaster – 52.1 miles – Charge before return
  • Sunderland via Northallerton – 47.4 miles

Note.

  1. The first place after the ‘via’ is where the electrification ends.
  2. Cleethorpes is a possible new service for Grand Central.
  3. ‘Charge before return’ means the train must be charged before return.

All of these routes would be possible with a battery-electric train with a hundred mile traction battery.

The hundred mile traction battery would also allow Grand Central to use the Lincoln diversion.

Avanti West Coast

These are distances from the electrification of the West Coast Main Line for Avanti West Coast’s services.

  • Chester via Crewe – 21.1 miles
  • Gobowen via Wolverhampton – 47.7 miles
  • Holyhead via Crewe – 105.5 miles – Charge before return
  • Shrewsbury via Wolverhampton – 29.7 miles
  • Wrexham via Crewe – 33.3 miles

Note.

  1. The first place after the ‘via’ is where the electrification ends.
  2. Gobowen is a possible new service for Avanti West Coast.
  3. ‘Charge before return’ means the train must be charged before return.

All of these routes would be possible with a battery-electric train with a hundred mile traction battery.

Great Western Railway

These are distances from the electrification of the Great Western Main Line for Great Western Railway’s services.

  • Bristol Temple Meads via Chippenham – 24.4 miles
  • Carmarthen via Cardiff Central – 77.4 miles – Charge before return
  • Cheltenham Spa via Swindon – 43.2 miles
  • Exeter St. Davids via Newbury – 120.4 miles – Charge before return
  • Great Malvern via Didcot East junction – 76.1 miles – Charge before return
  • Hereford via Didcot East junction – 96.9 miles – Charge before return
  • Oxford via Didcot Parkway – 10.3 miles
  • Paignton via Newbury – 148.7 miles – Charge before return
  • Pembroke Dock via Cardiff Central – 121.6 miles – Charge before return
  • Penzance via Newbury – 172.6 miles – Charge before return
  • Plymouth via Newbury – 120.4 miles – Charge before return
  • Swansea via Cardiff Central – 53 miles – Charge before return
  • Weston-super-Mare via Chippenham – 43.8 miles
  • Worcester Foregate Street via Didcot East junction – 68.2 miles – Charge before return
  • Worcester Shrub Hill via Didcot East junction – 67.6 miles – Charge before return

Note.

  1. The first place after the ‘via’ is where the electrification ends.
  2. ‘Charge before return’ means the train must be charged before return.
  3. Partial electrification through Hereford, Great Malvern, Worcester Foregate Street and Worcester Shrub Hill, could possibly be used to charge services from Hereford and Worcester.
  4. Partial electrification through Penzance, Plymouth and Exeter St. Davids, could possibly be used to charge services from the South West.
  5. Partial electrification West of Swansea, could possibly be used to charge services from West Wales.

All routes, except for Hereford and Worcester, the South-West and West Wales, would be possible with a battery-electric train with a hundred mile traction battery.

I’ll now look at the three groups of services in more detail.

Services To Hereford And Worcester

These are distances from the electrification of the Great Western Main Line for Great Western Railway’s Hereford and Worcester services.

  • Great Malvern via Didcot East junction – 76.1 miles
  • Hereford via Didcot East junction – 96.9 miles
  • Worcester Foregate Street via Didcot East junction – 68.2 miles
  • Worcester Shrub Hill via Didcot East junction – 67.6 miles

Note.

  1. All services join the Great Western Main Line at Didcot East junction.
  2. Some services will be probably need to have, their batteries charged at the Hereford and Worcester end.

At the present time, the electrification finishes at Didcot East junction, but if it were to be extended to Charlbury station, these would be the distances without electrification.

  • Great Malvern via Charlbury – 52.3 miles
  • Hereford via Charlbury – 73.1 miles
  • Worcester Foregate Street via Charlbury – 44.4 miles
  • Worcester Shrub Hill via Charlbury – 43.8 miles

Note.

  1. Some of the track between Oxford and Charlbury is only single track, which may give advantages, when it is electrified.
  2. It might be possible with a hundred mile traction battery for all Worcester services to charge their batteries between Charlbury and London Paddington and not need a charge at Worcester to return.
  3. A larger traction battery or extending the electrification to perhaps Morton-in-Marsh could see Great Malvern in range of battery-electric trains from London Paddington without a charge.
  4. Hereford would probably be too far to get away without charging at Hereford.

This OpenRailwayMap shows the layout of Hereford station.

I’m certain that a platform can be found, where there is space for a charger, which could also be used for other trains serving the station.

Services To The South West

In the August 2023 Edition of Modern Railways, there is an article, which is entitled GWR Seeks Opportunities To Grow.

This is the sub-heading.

Managing Director Mark Hopwood tells Philip Sherratt there is plenty of potential to increase rail’s economic contribution.

This is two paragraphs.

The desire to provide electrification to support aggregates traffic from the Mendip quarries could also benefit GWR , says Mr. Hopwood. ‘Having an electric loco would massively help with pathing heavy freight trains through the Thames Valley. If you could electrify from Newbury to East Somerset Junction, a big chunk of the Berks and Hants route would be wired.

Then you can ask how much further you could get on battery power on an IET without running out of juice.’

Newbury to East Somerset Junction would be 53.5 miles of electrification, so I can build this table of services to the South-West

  • Exeter St. Davids via Newbury – 120.4 miles – 66.9 miles
  • Paignton via Newbury – 148.7 miles – 95.2 miles
  • Penzance via Newbury – 251.9 miles – 198.5 miles
  • Plymouth via Newbury – 172.6 miles – 119 miles

Note.

  1. The distance between Penzance and Plymouth is 79.5 miles.
  2. The first figure in the table is the distance to Newbury.
  3. The second figure in the table is the distance to East Somerset junction.

A possible way of running these four services to London on battery power is emerging.

  • Exeter St. Davids via Newbury – Charge before return – Run on battery for 66.9 miles to East Somerset junction.
  • Paignton via Newbury – Charge before return – Run on battery for 95.2 miles to East Somerset junction.
  • Penzance via Newbury- Charge before return – Run on battery for 79.5 miles to Plymouth – Charge at Plymouth – Run on battery for 119 miles to East Somerset junction.
  • Plymouth via Newbury – Charge before return – Run on battery for 119 miles to East Somerset junction.

Once at East Somerset junction, it’s electrification all the way to Paddington.

This is the corresponding way to run services from London.

  • Exeter St. Davids via Newbury – Run on electrification to East Somerset junction, charging the battery on the way – Run on battery for 66.9 miles to Exeter St. Davids.
  • Paignton via Newbury – Run on electrification to East Somerset junction, charging the battery on the way – Run on battery for 95.2 miles to Paignton.
  • Penzance via Newbury – Run on electrification to East Somerset junction, charging the battery on the way – Run on battery for 119 miles to Plymouth – Charge at Plymouth – Run on battery for 79.5 miles to Penzance.
  • Plymouth via Newbury – Run on electrification to East Somerset junction, charging the battery on the way – Run on battery for 119 miles to Plymouth.

More electrification or a larger  than a hundred mile traction battery would be needed, as Plymouth and East Somerset junction is 119 miles.

But if a Stadler Akku can do 139 miles on a charge, why shouldn’t a Hitachi battery-electric train?

Services To West Wales

It seems that the current timetable is already setup for battery-electric trains to run to and beyond Swansea.

  • Carmarthen and Swansea is almost exactly 32 miles.
  • Pembroke Dock and Swansea is 73.4 miles.
  • Swansea and Cardiff Central is 45.7 miles.

Note

  1. All these sections could be run by a battery-electric train, with a fully-charged hundred mile traction battery.
  2. All trains going to or from Carmarthen or Pembroke Dock reverse at Swansea, where a generous time of more than eleven minutes is allowed for the manoeuvre.
  3. During the reverse at Swansea, there is sufficient time to charge the batteries, if overhead wires were present.

Battery-electric services could serve Wales Wales with overhead electrification at Carmarthen, Pembroke Dock and Swansea.

Conclusion

We will go a long way, if we embrace battery-electric trains.

Most routes can be handled with a train with a traction battery range of 100 miles.

Exceptions are.

  • Hazel Grove and Cleethorpes – 104.6 miles
  • Plymouth and East Somerset junction – 119 miles

But if a Stadler Akku can do 139 miles on a charge, why shouldn’t a Hitachi battery-electric train?

 

 

 

 

 

 

 

 

 

 

 

October 28, 2023 Posted by | Transport/Travel | , , , , , , , , , , , , , , | Leave a comment

Extra Luggage Racks For Lumo

The title of this post, is the same as a small article in the November 2023 Edition of Modern Railways.

Thiese are the first two paragraphs.

Lumo is to remove eight seats from each of its five Class 803 EMUs to make way for additional luggage racks.

Two seats will be removed from four of the five vehicles in each unit to make space for the luggage racks. The move has required a variation of Lumo’s track access agreement, with the Office of Road and Rail, which as originally approved specified that each train must have 400 seats.

The article also states that Lumo has stopped carrying bikes and the bike areas are now used for luggage.

Batteries For Lumo?

The article finishes with this paragraph.

Lumo celebrated its second birthday in late October and was also set to mark the carriage of its two-millionth passenger. It is understood Lumo is interested in augmenting its fleet, such has been the success of the service; while many operators favour bi-mode units, Lumo is proud of its all-electric credentials so straight EMUs are still preferred, although the possibilities of including batteries which could power the trains may be pursued (the ‘803s’ have on-board batteries, but only to provide power to on-board systems if the electricity supply fails).

I find this development very interesting.

As an electrical engineer, I’ve always believed that the emergency batteries in the Class 803 trains are very similar to the traction batteries that Hitachi are developing for the Class 802 trains.

  • One design of battery must surely save time and costs in design and testing.
  • The difference between the two batteries might be only software and the total capacity of the lithium-ion cells.
  • In service testing under real operating conditions can be carried out in Lumo’s Class 803 trains.
  • Traction and emergency batteries would be interchangeable, so some operators, who didn’t always need traction but wanted emergency on-board power could be setup as required for the route.

If traction batteries gave the train a range of perhaps 15-20 miles, this might well be enough range, for the train to get through or to the next station, if there was to be an incident like catenary failure or a derailed freight train blocking the line. Obviously, Lumo will have records of all external failures that have affected them.

Consider.

  • I have calculated that Peterborough and Doncaster via Lincoln is 88.5 miles.
  • I also believe it is likely that in the future, there may be some electrification at Lincoln to charge battery-electric trains.
  • Lincolnshire is flat.

Would it be possible for Lumo trains to use a single traction battery to take the Great Northern and Great Eastern Joint Line to get round engineering works on the East Coast Main Line?

What Length Of Trains Could Lumo Run?

In Ten-Car Hull Trains, I talked about Hull Trains running ten-car trains to Hull.

I would expect that all Lumo’s stops are possible with ten-car trains.

As the trains are all Plug-and-Play, Lumo could either run pairs of trains or perhaps lengthen all trains to any size between six and nine cars.

Could Lumo Piggy-Back An Aberdeen Service On An Edinburgh Train?

The line between Edinburgh and Ladybank is being electrified and Ladybank is just 91.4 miles South of Aberdeen.

  • A pair of Class 803 trains could leave King’s Cross running as a ten-car formation.
  • The leading train would be a Class 803 train equipped with a traction battery.
  • The trailing train would be a Class 803 train equipped with the normal emergency battery.
  • Aberdeen passengers would get in the leading train.
  • The train would run as normal to Edinburgh.
  • At Edinburgh the two trains would split with the leading train going on to Aberdeen and the trailing train getting ready to return to London.

The train going to Aberdeen would need sufficient battery range to cover the 91.4 miles to Aberdeen, where it would recharge to make the journey back to Ladybank, Edinburgh and the South.

What About Inverness?

Dunblane is the nearest electrified station to Inverness, but it is 146.2 miles away over a route with lots of steep climbs.

I doubt that a battery-electric train could handle that route.

Conclusions

Luggage seems to be getting more of a problem on trains and buses.

It does appear that a very innovative battery philosophy from Hitachi is emerging.

October 25, 2023 Posted by | Transport/Travel | , , , , , , , , , , | 5 Comments

Electrification Of The Hope Valley Line

This news story from the Department of Transport is entitled Yorkshire And The Humber To Benefit From £19.8 billion Transport Investment.

This is said about the Hope Valley Line.

The Hope Valley Line between Manchester and Sheffield will also be electrified and upgraded, with the aim of cutting journey times from 51 to 42 minutes and increasing the number of fast trains on the route from 2 to 3 per hour, doubling capacity.

The fast trains are currently TransPennine’s service between Liverpool Lime Street and Cleethorpes.

  • Between Platform 13 at Manchester Piccadilly station and Sheffield station is 42.6 miles.
  • At the Manchester end, there will be electrification between Manchester Piccadilly and Hazel Grove stations, which is 8.7 miles and takes typically 17 minutes.
  • After the electrification of the Midland Main Line to Sheffield, there will be electrification between Dore & Totley and Sheffield stations, which is 4.2 miles and takes typically 8 minutes.

The gap in the electrification between Dore & Totley and Hazel Grove stations will be 29.7 miles.

But it will not be an easy route to electrify.

  • At the Western end, there is the Disley Tunnel, which is 3535 metres long.
  • In the middle, there is the Cowburn Tunnel which is 3385 metres long, that is also the deepest tunnel in England.
  • At the Eastern end, there is the Totley Tunnel, which is 5700 metres long.

Yorkshire doesn’t have an Underground railway, but the combined length of these three tunnels is 7.84 miles, which means that over 26 % of the electrification needed between Manchester Piccadilly and Sheffield will have to be installed in tunnels.

Could The Route Be Run Using Battery-Electric Trains?

Consider.

  • The gap in the electrification between Dore & Totley and Hazel Grove stations will be 29.7 miles.
  • There is electrified sections at Dore & Totley and Hazel Grove stations, which will be able to charge the trains.
  • Merseyrail’s Class 777 trains have demonstrated a battery range of 84 miles.
  • A Stadler Akku train has demonstrated a battery range of 139 miles.
  • Hitachi are developing a battery-electric version of TransPennine’s Class 802 train.
  • If all trains can run on batteries or be self-powered, there would be no need to electrify the long and possibly difficult tunnels.

I believe that it would be possible to electrify all passenger services between Manchester and Sheffield using appropriate battery-electric trains.

Freight would be a problem and I suspect that hydrogen-hybrid and other self-powered locomotives could handle the route.

Could The Complete TransPennine Liverpool Lime Street and Cleethorpes Service Be Run By Battery-Electric Class 802 trains?

These are the various electrified and unelectrified sections.

  • Liverpool Lime Street and Liverpool South Parkway – Electrified – 5.7 miles – 10 minutes
  • Liverpool South Parkway and Trafford Park  – Not Electrified – 25.2 miles – 30 minutes
  • Trafford Park and Hazel Grove  – Electrified – 12.6 miles – 28 minutes
  • Hazel Grove and Dore & Totley  – Not Electrified – 29.7 miles – 35 minutes
  • Dore & Totley and Sheffield  – Electrified – 4.2 miles – 6 minutes
  • Sheffield and Doncaster  – Not Electrified – 18.6 miles – 25 minutes
  • Doncaster and Cleethorpes  – Not Electrified – 52.1 miles – 78 minutes

Note.

  1. This is a total of 125.6 miles without electrification.
  2. The Manchester Piccadilly and Sheffield time is 56 minutes.
  3. The distance is 37.8 miles.
  4. That is an average speed on 40.5 mph.
  5. Most of the line between Manchester Piccadilly and Sheffield has an maximum speed of 70 mph, but there is a short length of track with a 50 mph speed and another longer one with 90 mph.

To achieve 40 minutes between Manchester Piccadilly and Sheffield would need an average speed of 60.7 mph. Given the improvements being carried out by Network Rail at the current time, I believe that forty minutes between Manchester Piccadilly and Sheffield should be possible.

I’ll look at a train going East.

  • The train will leave Liverpool Lime Street with a reasonably full battery after charging using the current electrification in the station.
  • The train will leave Liverpool South Parkway with a full battery after charging using the current electrification from Liverpool Lime Street.
  • The train will arrive at Trafford Park with a battery perhaps two-thirds full, but it will be fully charged on the current electrification to Hazel Grove.
  • The train will arrive at Dore & Totley with a battery perhaps two-thirds full, but it will be fully charged on the Midland Main Line electrification to Sheffield.
  • The train will arrive at Doncaster with a battery perhaps two-thirds full and the train would wait until it had enough charge to reach Cleethorpes.

I’ll look at a train going West.

  • The train will leave Cleethorpes with a full battery after charging using the new electrification in the station.
  • The train will arrive at Doncaster with a battery perhaps two-thirds full and the train would wait until it had enough charge to reach Sheffield.
  • The train will arrive at Sheffield with a battery perhaps two-thirds full, but it will be fully charged on the Midland Main Line electrification to Dore & Totley.
  • The train will arrive at Hazel Grove with a battery perhaps two-thirds full, but it will be fully charged on the current electrification to Trafford Park.
  • The train will arrive at Liverpool South Parkway with a battery perhaps two-thirds full, but the route is electrified to Liverpool Lime Street.

Note.

  1. If the battery range on a full battery was over 90 miles, the two most easterly sections could be run without any charging at Doncaster.
  2. If the battery range was over 125.6 miles, the journey could be done by starting with a full battery.
  3. If every time the train decelerated, regenerative braking would recover energy, which could be reused.
  4. The only new electrification needed will be a short length at Cleethorpes station, that would charge the trains.

I certainly believe that Liverpool Lime Street and Cleethorpes services could be run by battery-electric trains.

Could The Complete TransPennine Liverpool Lime Street and Cleethorpes Service Be Run By Battery-Electric Class 802 trains Without The Midland Main Line Electrification?

In this section, I’m assuming, that there is no electrification at Sheffield.

These would be the various electrified and unelectrified sections.

  • Liverpool Lime Street and Liverpool South Parkway – Electrified – 5.7 miles – 10 minutes
  • Liverpool South Parkway and Trafford Park  – Not Electrified – 25.2 miles – 30 minutes
  • Trafford Park and Hazel Grove  – Electrified – 12.6 miles – 28 minutes
  • Hazel Grove and Cleethorpes  – Not Electrified – 104.6 miles – 143 minutes

Note.

  1. This is a total of 129.6 miles without electrification.
  2. The battery range of the train, should probably be around 120 miles to make sure the train could run between Hazel Grove and Cleethorpes.
  3. One diesel power-pack could be installed for emergency use.

I’ll look at a train going East.

  • The train will leave Liverpool Lime Street with a reasonably full battery after charging using the current electrification in the station.
  • The train will leave Liverpool South Parkway with a full battery after charging using the current electrification from Liverpool Lime Street.
  • The train will arrive at Trafford Park with a battery perhaps 80 % full, but it will be fully charged on the current electrification to Hazel Grove.
  • The train would then eek out what power it had left to reach Cleethorpes.

If necessary, the train could stop in the electrified Doncaster station to top up the batteries from the East Coast Main Line electrification for the run to Cleethorpes.

I’ll look at a train going West.

  • The train will leave Cleethorpes with a full battery after charging using new electrification in the station.
  • The train will arrive at Doncaster with a battery perhaps 57 % full and the train would wait if needed, until it had enough charge to reach Hazel Grove.
  • The train will arrive at Hazel Grove with a battery perhaps one-thirds full, but it will be fully charged on the current electrification to Trafford Park.
  • The train will arrive at Liverpool South Parkway with a battery perhaps one-thirds full, but the route is electrified to Liverpool Lime Street.

Note.

  1. If the battery range on a full battery was over 105 miles, the Eastern section could be run without any charging at Doncaster.
  2. If the battery range was over 129.6 miles, the journey could be done by starting with a full battery.
  3. If every time the train decelerated, regenerative braking would recover energy, which could be reused.
  4. The only new electrification needed will be a short length at Cleethorpes station, that would charge the trains.

However, it might be prudent to electrify the through platforms at Sheffield, so that they could be used for emergency charging if required.

Northern Train’s Service Between Sheffield And Manchester Piccadilly Via The Hope Valley Line

There is a one train per hour (tph) Northern service between Sheffield and Manchester Piccadilly.

  • The Class 195 diesel train takes 78 minutes.
  • The distance is 42 miles.
  • The first mile or so at the Manchester end is electrified.
  • Trains seem to take about sixteen minutes to turn round at Manchester Piccadilly.
  • Trains seem to take about nine minutes to turn round at Sheffield.
  • The service runs via Reddish North, Brinnington, Bredbury, Romiley, Marple, New Mills Central, Chinley, Edale, Hope, Bamford, Hathersage, Grindleford and Dore & Totley.
  • The max speed is generally 60 mph to the West of New Mills Central and 70 mph to the East, with short lower speed sections.

There would appear to be two ways to run this route withy battery-electric trains.

  • As Manchester Piccadilly station is fully-electrified and trains could be connected to the electrification for upwards of twenty minutes, trains will certainly be able to be fully-charged at Manchester. As the round trip is only 84 miles, could trains run the service without a charge at Sheffield.
  • Alternatively, there could be a dedicated electrified platform at Sheffield. But the problem with this, is that currently this service uses a random platform at Sheffield.

It looks like, if the train has the required range, that charging at the Manchester end would be the better solution.

Liverpool And Norwich Via The Hope Valley Line

This service uses a similar route between Liverpool Lime Street and Sheffield, as the Liverpool and Hull service and then it meanders, through the East Midlands.

  • Liverpool Lime Street and Liverpool South Parkway – Electrified – 5.7 miles – 11 minutes
  • Liverpool South Parkway and Trafford Park  – Not Electrified – 25.2 miles – 33 minutes
  • Trafford Park and Hazel Grove  – Electrified – 12.6 miles – 26 minutes
  • Hazel Grove and Dore & Totley  – Not Electrified – 29.7 miles – 28 minutes
  • Dore & Totley and Sheffield  – Electrified – 4.2 miles – 6 minutes
  • Sheffield and Nottingham – Being Electrified – 40.6 miles – 52 minutes
  • Nottingham and Grantham – Not Electrified – 22.7 miles – 30 minutes
  • Grantham and Peterborough – Electrified – 29.1 miles – 29 minutes
  • Peterborough And Ely – Not Electrified – 30 miles – 31 minutes
  • Ely and Norwich – Not Electrified – 53.7 miles – 56 minutes

This is a total of 161.3 miles without electrification.

But as Sheffield and Nottingham and Grantham and Peterborough will be fully electrified, this route will be possible using a battery-electric train.

Electrifying Sheffield Station

I said earlier in this post, that electrifying Sheffield station would be an option for electrifying the Sheffield and Manchester Piccadilly service.

If this were to be done, it would have collateral benefits for other services that terminate at Sheffield, which could be charged whilst they turned around.

I wrote about Sheffield station as a battery-electric train hub in Could Sheffield Station Become A Battery-Electric Train Hub?

Conclusion

I believe that full electrification of the Hope Valley Line is not needed, if battery-electric trains are used.

I also believe that battery-electric trains and the current improvements being carried out on the Hope Valley Line will enable a forty minute time between Manchester Piccadilly and Sheffield.

 

 

October 15, 2023 Posted by | Transport/Travel | , , , , , , , , , , , , , , , , , | 5 Comments

Is There An ERTMS-based Solution To The Digswell Viaduct?

Consider.

  • Airliners have been flown automatically and safely from airport to airport for perhaps four decades.
  • The Victoria Line has been running automatically and safely at over twenty tph for five decades.
  • I worked with engineers developing a high-frequency sequence control system for a complicated chemical plant in 1970.

We also can’t deny that computers are getting better and more capable.

For these reasons, I believe there could be an ERTMS-based solution to the problem of the Digswell Viaduct, which could be something like this.

  • All trains running on the two track section over the Digswell Viaduct and through Welwyn North station would be under computer control between Welwyn Garden City and Knebworth stations.
  • Fast trains would be slowed as appropriate to create spaces to allow the slow trains to pass through the section.
  • The driver would be monitoring the computer control, just as they do on the Victoria Line.

Much more complicated automated systems have been created in various applications.

The nearest rail application in the UK, is probably the application of digital signalling to London Underground’s Circle, District, Hammersmith & City and Metropolitan Lines.

This is known at the Four Lines Modernisation and it will be completed by 2023 and increase capacity by up to twenty-seven percent.

I don’t think it unreasonable to see the following numbers of services running over the Digswell Viaduct by 2030 in both directions in every hour.

  • Sixteen fast trains
  • Four slow trains

That is one train every three minutes.

Currently, it appears to be about ten fast and two slow.

As someone, who doesn’t like to be on a platform, when a fast train goes through, I believe that some form of advanced safety measures should be installed at Welwyn North station.

Conclusion

It will surely be more affordable to use clever signalling and train sequencing, than rebuilding the viaduct with four tracks.

September 15, 2023 Posted by | Transport/Travel | , , , | 8 Comments

Derby Alstom Train Factory Jobs Fear As Orders Dry Up

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

This is the sub-heading.

Derby City Council is seeking talks with train builder Alstom over reports it could be about to lay off workers.

These two paragraphs introduce the story.

The firm’s Litchurch Lane site is the only UK train factory able to design, build, engineer and test trains for domestic and export markets.

About 2,000 people work at the factory but the firm says its current order book only runs until early 2024.

This could be another serious problem for High Speed Two.

Could LNER Use High Speed Two Classic-Compatible Trains?

In LNER Seeks 10 More Bi-Modes, I discuss how LNER are needing ten more bi-mode trains to expand their services.

Consider.

  • One of LNER’s predecessors used to run Eurostar trains between Kings Cross and Leeds
  • A High Speed Two Classic-Compatible trains are 200 metres long, as against the 233.7 metres of a nine-car Class 801 train.
  • High Speed Two Classic-Compatible trains will run on the East Coast Main Line, when High Speed Two fully opens.
  • London to Doncaster, Edinburgh, Leeds, Newcastle and York are all fully electrified routes.

So if all these fully-electric routes, were to be run using High Speed Two Classic-Compatible trains, this would release a number of Class 800 and Class 801 trains, which could be converted to bi-modes or battery-electric variants.

London and Edinburgh In Three-And-A-Half Hours

This is a paragraph from the Wikipedia entry for the InterCity 225 train.

The InterCity 225 was designed to achieve a peak service speed of 140 mph (225 km/h); during a test run in 1989 on Stoke Bank between Peterborough and Grantham, an InterCity 225 was recorded at a speed of 162 mph (260.7 km/h). Its high speed capabilities were again demonstrated via a 3hr 29mins non-stop run between London and Edinburgh on 26 September 1991. British regulations have since required in-cab signalling on any train running at speeds above 125 mph (201 km/h) preventing such speeds from being legally attained in regular service. Thus, except on High Speed 1, which is equipped with cab signalling, British signalling does not allow any train, including the InterCity 225, to exceed 125 mph (201 km/h) in regular service, due to the impracticality of correctly observing lineside signals at high speed.

If in-cab digital signalling were to be installed between London and Edinburgh, I believe that the three-and-a-half hour timing can be regularly achieved by a High Speed Two Classic-Compatible train.

I also believe that at least one train per hour (tph) between London and Edinburgh could achieve the three-and-a-half hour timing.

High Speed Two are promising a 3:48 time between London and Edinburgh.

It could be a Lumo-squasher!

A one tph service would need eight trains, but would release eight nine-car Class 801 trains.

Euston and Glasgow

This might be another route, where High Speed Two Classic-Compatible trains could be used.

Conclusion

LNER gets some more trains and Derby gets more work.

But the biggest benefits would be that, the trains would get a thorough testing before High Speed Two opens and passengers would get a view of the shape of things to come.

September 15, 2023 Posted by | Transport/Travel | , , , , , , , , , , | 4 Comments

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