The Anonymous Widower

Are Hitachi Designing the Ultimate Battery Train?

In Sparking A Revolution, a post based on an article of the same name in Issue 898 of Rail Magazine, I repeated this about the specification of Hitachi UK Battery Train Specification.

  • Range – 55-65 miles
  • Performance – 90-100 mph
  • Recharge – 10 minutes when static
  • Routes – Suburban near electrified lines
  • Battery Life – 8-10 years

Does this mean that the train can do 55-65 miles cruising at 90-100 mph?

How Much Energy Is Needed To Accelerate A Five-Car Class 800 Train To Operating Speed?

I will do my standard calculation.

  • Empty train weight – 243 tonnes (Wikipedia for Class 800 train!)
  • Passenger weight – 302 x 90 Kg (Includes baggage, bikes and buggies!)
  • Train weight – 270.18 tonnes

Using Omni’s Kinetic Energy Calculator, the kinetic energy at various speeds are.

  • 60 mph – 27 kWh
  • 80 mph – 48 kWh
  • 90 mph – 61 kWh
  • 100 mph – 75 kWh
  • 125 mph – 117 kWh – Normal cruise on electrified lines.
  • 140 mph – 147 kWh – Maximum cruise on electrified lines.

Because the kinetic energy of a train is only proportional to the weight of the train, but proportional to the square of the speed, note how the energy of the train increases markedly after 100 mph.

Are these kinetic energy figures a reason, why Hitachi have stated their battery train will have an operating speed of between 90 and 100 mph?

A 100 mph cruise would also be very convenient for a lot of main lines, that don’t have electrification in the UK.

What Battery Size Would Be Needed?

In How Much Power Is Needed To Run A Train At 125 mph?, I calculated that a five-car Class 801 electric train, needed 3.42 kWh per vehicle-mile to maintain 125 mph.

For comparison, an InterCity 125 train, had a figure of 2.83 kWh per vehicle-mile.

Hitachi are redesigning the nose of the train for the new Class 804 train and I suspect that these trains can achieve somewhere between 1.5 and 3 kWh per vehicle-mile, if they are cruising at 100 mph.

Doing the calculation for various consumption levels gives the following battery capacity for a five-car train to cruise 65 miles at 100 mph

  • 1.5 kWh per vehicle-mile – 487 kWh
  • 2 kWh per vehicle-mile – 650 kWh
  • 2.5 kWh per vehicle-mile – 812.5 kWh
  • 3 kWh per vehicle-mile – 975 kWh

These figures don’t include any energy for acceleration to line speed from the previous stop or station, but they would cope with a deceleration and subsequent acceleration, after say a delay caused by a slow train or other operational delay, by using regenerative braking to the battery.

The energy needed to accelerate to operating speed, will be as I calculated earlier.

  • 90 mph – 61 kWh
  • 100 mph – 75 kWh

As the battery must have space to store the regenerative braking energy and it would probably be prudent to have a ten percent range reserve, I can see a battery size for a train with an energy consumption of 2 kWh per vehicle-mile, that needed to cruise at 100 mph being calculated as follows.

  • Energy for the cruise – 650 kWh
  • 10% reserve for cruise – 65 kWh
  • Braking energy from 100 mph – 75 kWh

This gives a total battery size of 790 kWh, which could mean that 800 kWh would be convenient.

Note that each of the three MTU 12V 1600 diesel engines, fitted to a Class 800 train, each weigh around two tonnes.

In Innolith Claims It’s On Path To 1,000 Wh/kg Battery Energy Density, I came to these conclusions.

  • Tesla already has an energy density of 250 Wh/Kg.
  • Tesla will increase this figure.
  • By 2025, the energy density of lithium-ion batteries will be much closer to 1 KWh/Kg.
  • Innolith might achieve this figure. But they are only one of several companies aiming to meet this magic figure.

Suppose two of the MTU 12V 1600 diesel engines were each to be replaced by a two tonne battery, using Tesla’s current energy density, this would mean the following.

  • Each battery would have a capacity of 500 kWh.
  • The train would have one MWh of installed battery power.
  • This is more than my rough estimate of power required for a 65 mile trip.
  • The train would have little or no weight increase.
  • I also wouldn’t be surprised to find that the exchange of a diesel engine for a battery was Plug-and-Play.

Hitachi would have an electric/battery/diesel tri-mode train capable of the following.

  • Range – 55-65 miles
  • Out and Back Range – about 20-30 miles
  • Performance – 90-100 mph
  • Recharge – 10 minutes when static
  • Emergency diesel engine.

I feel it would be a very useful train.

Trains That Could Be Fitted With Batteries

The original article in Rail Magazine says this.

For the battery project, positive discussions are taking place with a number of interested parties for a trial, with both Class 385s and Class 800s being candidates for conversion.

So this means that the following operators will be able to use Hitachi’s battery technology o their trains.

  • Avanti West Coast – Class 80x trains
  • First East Coast Trains – Class 80x trains
  • East Midlands Railway – Class 80x trains
  • GWR – Class 80x trains
  • Hull Trains – Class 80x trains
  • LNER – Class 80x trains
  • ScotRail – Class 385 trains
  • TransPennine Express – Class 80x trains

Although, I based my calculations on Class 80x trains, I suspect that the methods can be applied to the smaller Class 385 trains.

Possible Out-And-Back Journeys

These are possible Out-And-Back journeys, that I believe Hitachi’s proposed battery-electric trains could handle.

  • Edinburgh and Tweedbank – 30 miles from Newcraighall
  • London Paddington and Bedwyn – 30 miles from Reading
  • London Euston and Blackburn – 12 miles from Preston
  • London Kings Cross and Bradford – < 27 miles from Leeds
  • London Euston and Chester – 21 miles from Crewe
  • London Kings Cross and Harrogate – <18 miles from Leeds
  • London Kings Cross and Huddersfield – 17 miles from Leeds
  • London St. Pancras and Leicester – 16 miles from Market Harborough
  • London Kings Cross and Lincoln – 17 miles from Newark
  • London St. Pancras and Melton Mowbray – 26 miles from Corby
  • London Kings Cross and Middlesbrough – 20 miles from Northallerton
  • London Kings Cross and Nottingham – 20 miles from Newark
  • London Paddington and Oxford – 10 miles from Didcot
  • London Kings Cross and Redcar – 29 miles from Northallerton
  • London Kings Cross and Rotherham- 14 miles from Doncaster
  • London Kings Cross and Sheffield – 20 miles from Doncaster
  • London and Weston-super-Mare – 19 miles from Bristol

Note.

  1. Provided that the Out-And-Back journey is less than about sixty miles, I would hope that these stations are comfortably in range.
  2. Leicester is the interesting destination, which would be reachable in an Out-And-Back journey. But trains from the North stopping at Leicester would probably need to charge at Leicester.
  3. I have included Blackburn as it could be a destination for Avanti West Coast.
  4. I have included Melton Mowbray as it could be a destination for East Midlands Railway.
  5. I have included Nottingham, Rotherham and Sheffield as they could be destinations for LNER. These services could prove useful if the Midland Main Line needed to be closed for construction works.
  6. I’m also fairly certain, that no new electrification would be needed, although every extra mile would help.
  7. No charging stations would be needed.

I suspect, I’ve missed a few possible routes.

Possible Journeys Between Two Electrified Lines

These are possible journeys between two electrified lines, that  I believe Hitachi’s proposed battery-electric trains could handle.

  • London St. Pancras and Eastbourne via Hastings – 25 miles between Ashford and Ore.
  • Leeds and York via Garforth – 20 miles between Neville Hall and Colton Junction
  • London Kings Cross and Norwich via Cambridge – 54 miles between Ely and Norwich.
  • Manchester Victoria and Leeds via Huddersfield – 43 miles between Manchester Victoria and Leeds.
  • Preston and Leeds via Hebden Bridge – 62 miles between Preston and Leeds.
  • Newcastle and Edinburgh – Would battery-electric trains get round the well-publicised power supply problems on this route?

Note.

  1. I am assuming that a range of 65 miles is possible.
  2. If the trains have a diesel-generator set, then this could be used to partially-charge the battery in places on the journey.
  3. Leeds and York via Garforth has been scheduled for electrification for years.
  4. Preston and Leeds via Hebden Bridge would probably need some diesel assistance.
  5. London Kings Cross and Norwich via Cambridge is a cheeky one, that Greater Anglia wouldn’t like, unless they ran it.
  6. As before no new electrification or a charging station would be needed.

I suspect, I’ve missed a few possible routes.

Possible Out-And-Back Journeys With A Charge At The Destination

These are possible Out-And-Back journeys, that I believe Hitachi’s proposed battery-electric trains could handle, if the batteries were fully charged at the destination.

  • Doncaster and Cleethorpes – 52 miles from Doncaster.
  • London Paddington and Cheltenham – 42 miles from Swindon
  • London Kings Cross and Cleethorpes via Lincoln – 64 miles from Newark
  • London Euston and Gobowen – 46 miles from Crewe
  • London Euston and Wrexham – 33 miles from Crewe
  • London Kings Cross and Hull – 45 miles from Selby
  • London Kings Cross and Shrewsbury – 30 miles from Wolverhampton
  • London Kings Cross and Sunderland 41 miles from Northallerton
  • London Paddington and Swansea – 46 miles from Cardiff
  • London Paddington and Worcester – 67 miles from Didcot Parkway
  • London St. Pancras and Derby – 46 miles from Market Harborough
  • London St. Pancras and Nottingham – 43 miles from Market Harborough

Note.

  1. I am assuming that a range of 65 miles is possible.
  2. If the trains have a diesel-generator set, then this could be used to partially-charge the battery in places on the journey.
  3. I am assuming some form of charging is provided at the destination station.
  4. As before no new electrification would be needed.

I suspect, I’ve missed a few possible routes.

Midland Main Line

The Midland Main Line could possibly be run between London St. Pancras and Derby, Nottingham and Sheffield without the use of diesel.

Consider.

  • The route will be electrified between London St. Pancras and Market Harborough.
  • In connection with High Speed Two, the Midland Main Line and High Seed Two will share an electrified route between Sheffield and Clay Cross North Junction.
  • London St. Pancras and Derby can be run with a charging station at Derby, as Market Harborough and Derby is only 46 miles.
  • London St. Pancras and Nottingham can be run with a charging station at Nottingham, as Market Harborough and Nottingham is only 43 miles.
  • The distance between Clay Cross North Junction and Market Harborough is 67 miles.
  • The distance between Sheffield and Leeds is 38 miles.

It looks to me that the range of East Midlands Railway’s new Class 804 trains, will be a few miles short to bridge the gap on batteries, between Clay Cross North Junction and Market Harborough station, but Leeds and Sheffield appears possible, once Sheffield has been electrified.

There are several possible solutions to the Clay Cross North and Market Harborough electrification gap.

  1. Fit higher capacity batteries to the trains.
  2. Extend the electrification for a few miles North of Market Harborough station.
  3. Extend the electrification for a few miles South of Clay Cross North Junction.
  4. Stop at Derby for a few minutes to charge the batteries.

The route between Market Harborough and Leicester appears to have been gauge-cleared for electrification, but will be difficult to electrify close to Leicester station. However, it looks like a few miles can be taken off the electrification gap.

Between Chesterfield and Alfriston, the route appears difficult to electrify with tunnels and passig through a World Heritage Site.

So perhaps options 1 and 2 together will give the trains sufficient range to bridge the electrification gap.

Conclusion On The Midland Main Line

I think that Hitachi, who know their trains well, must have a solution for diesel-free operation of all Midland Main Line services.

It also looks like little extra electrification is needed, other than that currently planned for the Midland Main Line and High Speed Two.

North Wales Coast Line

If you look at distance along the North Wales Coast Line, from the electrification at Crewe, you get these values.

  • Chester – 21 miles
  • Rhyl – 51 miles
  • Colwyn Bay – 61 miles
  • Llandudno Junction – 65 miles
  • Bangor – 80 miles
  • Holyhead – 106 miles

It would appear that Avanti West Coast’s new AT-300 trains, if fitted with batteries could reach Llandudno Junction station, without using diesel.

Electrification Between Crewe And Chester

It seems to me that the sensible thing to do for a start is to electrify the twenty-one miles between Crewe and Chester, which has been given a high priority for this work.

With this electrification, distances from Chester are as follows.

  • Rhyl – 30 miles
  • Colwyn Bay – 40 miles
  • Llandudno Junction – 44 miles
  • Bangor – 59 miles
  • Holyhead – 85 miles

Electrification between Crewe and Chester may also open up possibilities for more electric and battery-electric train services.

But some way will be needed to charge the trains to the West of Chester.

Chagring The Batteries At Llandudno Junction Station

This Google Map shows Llandudno Junction station.

Note.

  1. It is a large station site.
  2. The Conwy Valley Line, which will be run by battery Class 230 trains in the future connects at this station.
  3. The Class 230 train will probably use some of Vivarail’s Fast Charging systems, which use third-rail technology, either at the ends of the branch or in Llandudno Junction station.

The simplest way to charge the London Euston and Holyhead train, would be to build a charging station at Llandudno Junction, which could be based on Vivarail’s Fast Charging technology or a short length of 25 KVAC overhead wire.

But this would add ten minutes to the timetable.

Could 25 KVAC overhead electrification be erected for a certain distance through the station, so that the train has ten minutes in contact with the wires?

Looking at the timetable of a train between London Euston and Holyhead, it arrives at Colwyn Bay station at 1152 and leaves Llandudno Junction station at 1200.

So would it be possible to electrify between the two stations and perhaps a bit further?

This Google Map shows Colwyn Bay Station,

Note how the double-track railway is squeezed between the dual-carriageway of the A55 North Wales Expressway and the sea.

The two routes follow each other close to the sea, as far as Abegele & Pensarn station, where the Expressway moves further from the sea.

Further on, after passing through more caravans than I’ve ever seen, there is Rhyl station.

  • The time between arriving at Rhyl station and leaving Llandudno Junction station is nineteen minutes.
  • The distance between the two stations is fourteen miles.
  • Rhyl and Crewe is fifty-one miles.
  • Llandudno Junction and Holyhead is forty-one miles.

It would appear that if the North Wales Coast Line between Rhyl and Llandudno Junction is electrified, that Hitachi’s proposed battery trains can reach Holyhead.

The trains could even changeover between electrification and battery power in Rhyl and Llandudno Junction stations.

I am sure that electrifying this section would not be the most difficult in the world, although the severe weather sometimes encountered, may need some very resilient or innovative engineering.

It may be heretical to say so, but would it be better if this section were to be electrified using proven third-rail technology.

West of Llandudno Junction station, the electrification would be very difficult, as this Google Map of the crossing of the River Conwy shows.

I don’t think anybody would want to see electrification around the famous castle.

Electrification Across Anglesey

Llanfairpwll station marks the divide between the single-track section of the North Wales Coast Line over the Britannia Bridge and the double-track section across Anglesey.

From my virtual helicopter, the route looks as if, it could be fairly easy to electrify, but would it be necessary?

  • Llandudno Junction and Holyhead is forty-one miles, which is well within battery range.
  • There is surely space at Holyhead station to install some form of fast-charging system.

One problem is that trains seem to turn round in only a few minutes, which may not be enough to charge the trains.

So perhaps some of the twenty-one miles between Llanfairpwll and Holyhead should be electrified.

London Euston And Holyhead Journey Times

Currently, trains take three hours and forty-three minutes to go between London Euston and Holyhead, with these sectional timings.

  • London Euston and Crewe – One hour and thirty-nine minutes.
  • Crewe and Holyhead – Two hours and four minutes.

The big change would come, if the London Euston and Crewe leg, were to be run on High Speed Two, which will take just fifty-five m,inutes.

This should reduce the London Euston and Holyhead time to just under three hours.

Freight On The North Wales Coast Line

Will more freight be seen on the North Wales Coast Line in the future?

The new tri-mode freight locomotives like the Class 93 locomotive, will be able to take advantage of any electrification to charge their batteries, but they would probably be on diesel for much of the route.

Conclusion On The North Wales Coast Line

Short lengths of electrification, will enable Avanti West Coast’s AT-300 trains, after retrofitting with batteries, to run between Crewe and Holyhead, without using any diesel.

I would electrify.

  • Crewe and Chester – 21 miles
  • Rhyl and Llandudno Junction – 14 miles
  • Llanfairpwll and Holyhead – 21 miles

But to run battery-electric trains between London Euston and Holyhead, only Rhyl and Llandudno Junction needs to be electrified.

All gaps in the electrification will be handled on battery power.

A Selection Of Possible Battery-Electric Services

In this section, I’ll look at routes, where battery-electric services would be very appropriate and could easily be run by Hitachi’s proposed battery-electric trains.

London Paddington And Swansea

Many were disappointed when Chris Grayling cancelled the electrification between Cardiff and Swansea.

I went along with what was done, as by the time of the cancellation, I’d already ridden in a battery train and believed in their potential.

The distance between Cardiff and Swansea is 46 miles without electrification.

Swansea has these services to the West.

  • Carmarthen – 32 miles
  • Fishguard – 73 miles
  • Milford Haven  71 miles
  • Pembroke Dock – 73 miles

It looks like, three services could be too long for perhaps a three car battery-electric version of a Hitachi Class 385 train, assuming it has a maximum range of 65 miles.

But these three services all reverse in Carmarthen station.

So perhaps, whilst the driver walks between the cabs, the train can connect automatically to a fast charging system and give the batteries perhaps a four minute top-up.

Vivarail’s Fast Charging system based on third-rail technology would be ideal, as it connects automatically and it can charge a train in only a few minutes.

I would also electrify the branch between Swansea and the South Wales Main Line.

This would form part of a fast-charging system for battery-trains at Swansea, where turnround times can be quite short.

I can see a network of battery-electric services developing around Swansea, that would boost tourism to the area.

Edinburgh And Tweedbank

The Borders Railway is electrified as far as Newcraighall station and the section between there and Tweedbank is thirty miles long.

I think that a four-car battery-electric Class 385 train could work this route.

It may or may not need a top up at Tweedbank.

The Fife Circle

The Fife Circle service from Edinburgh will always be difficult to electrify, as it goes over the Forth Rail Bridge.

  • The Fife Circle is about sixty miles long.
  • Plans exist for a short branch to Leven.
  • The line between Edinburgh and the Forth Rail Bridge is partly electrified.

I believe that battery-electric Class 385 train could work this route.

London Kings Cross and Grimsby/Cleethorpes via Lincoln

The Cleethorpes/Grimsby area is becoming something of a  renewable energy powerhouse and I feel that battery trains to the area, might be a significant and ultimately profitable statement.

LNER recently opened a six trains per day service to Lincoln.

Distances from Newark are as follows.

  • Lincoln – 17 miles
  • Grimsby – 61 miles
  • Cleethorpes – 64 miles

A round trip to Lincoln can probably be achieved on battery alone with a degree of ease, but Cleethorpes and Grimsby would need a recharge at the coast.

Note that to get to the Cleethorpes/Grimsby area, travellers usually need to change at Doncaster.

But LNER are ambitious and I wouldn’t be surprised to see them dip a toe in the Cleethorpes/Grimsby market.

The LNER service would also be complimented by a TransPennine Express service from Manchester Airport via Sheffield and Doncaster, which could in the future be another service run by a Hitachi battery train.

There is also a local service to Barton-on-Humber, which could be up for improvement.

London Waterloo And Exeter

This service needs to go electric, if South Western Railway is going to fully decarbonise.

But third-rail electrification is only installed between Waterloo and Basingstoke.

Could battery-electric trains be used on this nearly two hundred mile route to avoid the need for electrification.

A possible strategy could be.

  • Use existing electrification, as far as Basingstoke – 48 miles
  • Use battery power to Salisbury – 83 miles
  • Trains can take several minutes at Salisbury as they often split and join and change train crew, so the train could be fast-charged.
  • Use battery power to the Tisbury/Gillingham/Yeovil/Crewkerne area, where trains would be charged – 130 miles
  • Use battery power to Exeter- 172 miles

Note.

  1. The miles are the distance from London.
  2. The charging at Salisbury could be based on Vivarail’s Fast-Charging technology.
  3. The charging around Yrovil could be based on perhaps twenty miles of third-rail electrification, that would only be switched on, when a train is present.

I estimate that there could be time savings of up to fifteen minutes on the route.

 

To Be Continued…

 

 

 

 

 

 

 

 

 

 

 

February 18, 2020 Posted by | Transport | , , , , , , , , , , , , , , , , , , , , , | 5 Comments

Sparking A Revolution

The title of this post is the same as that of an article in Issue 898 of Rail Magazine.

The sub-title is.

When it comes to powering a zero-enissions train with no overhead line infrastructure, battery power is clearly the answer, according to Hitachi.

These are the first three paragraphs.

Over the next decade around 1,000 diesel-powered vehicles will need to be replaced with vehicles that meet emissions standards.

Hitachi, which has been building bi-mode trains for the UK since 2012, and electric trains since 2006, says that retro-fitting old vehicles alone will not be good enough to improve capacity, reliability or passenger satisfaction.

Battery power is the future – not only as a business opportunity for the company, but more importantly for the opportunities it offers the rail industry.

Speaking is Andrew Barr of Hitachi Rail.

Some important points are made.

  • Hitachi has identified various towns and cities, where battery trains would be useful including Bristol, Edinburgh, Glasgow, Hastings, Leeds and Manchester.
  • Andrew Barr says he gets a lot of questions about battery power.
  • Battery power can be used as parts of electrification schemes to bridge gaps, where rebuilding costs of bridges and other infrastructure would be too high.
  • Battery trains are ideal for decarbonising branch lines.
  • Batteries could be fitted to Class 385, 800, 802 and 804 trains.

Hitachi would like to run a battery train with passengers, within the next twelve months.

The article also gives the specification of a Hitachi battery train.

  • Range – 55-65 miles
  • Performance – 90-100 mph
  • Recharge – 10 minutes when static
  • Routes – Suburban near electrified lines
  • Battery Life – 8-10 years

These figures are credited to Hitachi.

Hitachi are also thinking about tri-mode trains.

  • Batteries could be installed on Class 800-802/804 trains.
  • Battery-only power for stations and urban areas.
  • 20% performance improvements or 30% fuel savings.

These is also credited to Hitachi.

Costs And Power

This is an insert in the article, which will apply to all applications with traction batteries.

This is said.

The costs of batteries are expected to halve in the next five years, before dropping further again by 2030.

Hitachi cites research by Bloomberg New Energy Finance (BNEF) which expects costs to fall from £135/kWh at the pack level today to £67/kWh in 2025 and £47/kWh in 2030.

United Kingdom Research and Innovation (UKRI)  is also predicting that battery energy density will double in the next 15 years, from 700 Wh/l to 1,400 Wh/l in 2035, while power density (fast charging) is likely to increase four times in the same period from 3 kW/kg now to 12 kW/kg in 2035.

In Batteries On Class 777 Trains, I quoted a source that said that Class 777 trains are built to handle a five tonne battery.

I estimated the capacity as follows.

Energy densities of 60 Wh/Kg or 135 Wh/litre are claimed by Swiss battery manufacturer; Leclanche.

This means that a five tonne battery would hold 300 kWh.

Hitachi’s figures are much higher as it looks like a five tonne battery can hold 15 MWh.

Batteries will be going places on Hitachi trains.

 

February 16, 2020 Posted by | Energy Storage, Transport | , , , , , , | 14 Comments

Could High Speed Two Have A Station At Ashby-de-la-Zouch?

This morning, I was listening to Andrew Bridgen, who is the Member of Parliament for North West Leicestershire, giving the reasons for a strong opposition to High Speed Two.

  • High Speed Two will reduce the number of services between Leicester and London.
  • His constituency does not have a rail station.
  • His constituency would do better for the Ivanhoe Line to get a passenger service.
  • His constituents are badly affected by the building of the line.
  • His constituents will need to drive North to East Midlands Hub station to use High Speed Two.

Some points are valid, although I think no rail company would reduce the number of services between Leicester and London.

The Future Of Services Between Leicester And London

East Midlands Railway currently run four trains per hour (tph) between Leicester and London, with the fastest trains taking five minutes over the hour.

New 125 mph bi-mode Class 804 trains, will be running all main line services on the Midland Main Line from 2023, using electric power between London and Market Harborough.

It is also planned to increase the line speed between London and Market Harborough to 140 mph, so the trains can really use their design speed, by updating the electrification, signalling and track.

From these published plans, I would feel that East Midlands Railway are intending that all Leicester and London services are within the hour.

Reinstatement Of Services On The Ivanhoe Line

This has been promised off-and-on for some time and I wrote about it in Silent Hydrogen Trains On The Cards For New Line Linking Burton And Leicester, after one of my alerts picked up “hydrogen trains”.

The Association Of Train Operating Companies Plan For The Ivanhoe Line

This is taken from the Wikipedia entry for the Ivanhoe Line.

In 2009 the Association of Train Operating Companies published a £49 million proposal (Connecting Communities: Expanding Access to the Rail Network) to restore passenger services to the line that would include reopening stations at Kirby Muxloe, Bagworth and Ellistown, Coalville Town, Ashby de la Zouch, Moira, and Gresley (for Swadlincote). There is also some support in the Leicester area for the line to have new stations to serve Leicester City F.C.’s stadium and the suburb of Braunstone.

Wikipedia also says, it could be developed as a no-frills line.

Given the government’s enthusiasm for reopening lines closed by Beeching, I suspect that this line will be reopened to passenger traffic in the next few years.

Ashby-de-la-Zouch Station

This section of the route map for High Speed Two, shows where the Ivanhoe Line crosses it, just by a major road junction outside Ashby-de-la-Zouch.

Note.

  1. High Speed Two is shown in orange.
  2. The Ivanhoe Line runs West-East from the West edge of the map and after crossing the A42 and High Speed Two it curves South-East.

Where the two lines cross would it be sensible to build a simple interchange station?

  • Andrew Bridgen’s constituency has a electorate of over 72,000.
  • The station would be well-connected to the road network via the the M42, A42 and A51.
  • There would appear to be plenty of space for parking.
  • It would ease the problems of going by train between Leicester and Birmingham.
  • A bridge will have to be built at the location of the station to carry High Speed Two over the Ivanhoe Line, so why not design the bridge with simple platforms?
  • As High Speed Two’s trains will be designed with fast acceleration and deceleration, the stops would be very quick
  • Passengers would only be allowed on the High Speed Two platforms, when trains are in the station.

Perhaps given its location it could be called the Heart of England Parkway station?

The Station Site

This Google Map shows the station site.

Note.

  1. The Ivanhoe Line is at the bottom of the map.
  2. There is a spur from the line into the space.
  3. High Speed Two will run almost North-South parallel to the A42.

It looks like an abandoned open-cast coal-mine or quarry. Does anybody else know better?

Conclusion

There has already been speculation for the building of a similar station, which I wrote about in Should High Speed Two Have A Station At Calvert?, so perhaps it’s not a totally crazy idea,

Perhaps, there are other places, where High Speed Two crosses other main lines, where parkway stations could be built?

 

 

February 11, 2020 Posted by | Transport | , , , , , , , | 8 Comments

Mule Trains Between Liverpool And Norwich

I have done two trips to Liverpool in the last week.

On Saturday, I saw this collection of one-car Class 153 trains with a two-car Class 156 train thrown in.

They were forming one of East Midlands Railway‘s Liverpool and Norwich services.

And then yesterday, I had to travel between Liverpool and Sheffield and this was the collection of trains that took me.

So what was it like?

It started badly, with the driver announcing that because of the late arrival due to an undisclosed problem with the incoming train, that we would be leaving ten minutes after the planned departure time of 1551. He also indicated that our late departure meant that we would be stuck behind one of Northern’s services.

In the end, despite the gloomy faces of passengers we left twelve minutes late at 1603.

It was a bit like one of those classic films, where an ancient train escapes in the nick of time, with a lot of important and assorted passengers.

The asthmatic Cummins diesels under the train could be heard straining.

  • But the driver was at the top of his game and the train was running smoothly towards Manchester at close to 75 mph, which is the maximum speed of a Class 153 train.
  • At Manchester Piccadilly, the driver had pulled back two minutes.
  • There were obviously, no problems on the Dove Valley Line and the driver pulled back another minute before Sheffield, to arrive nine minutes late.

Looking at Real Time Trains, the train ran well until March (The place, not the month!), but there was some form of delay there and sadly it was thirty-four minutes late into Norwich.

The Train Was Clean

I should say there was nothing wrong with the train except for its design and age. It was also as clean as you can get one of these trains. The toilet, that I used was better than many I’ve used on trains and worked as it should.

Customer Service

East Midlands Railway had loaded a trolley and a steward and in the two hours I was on the train, he came through twice. The only problem for me, that he had no card machine, but I did find a fiver in my briefcase.

At least it was very drinkable. Even, if I hate those plastic tubs of milk, as they are difficult to open with one good hand.

Where Did Two Cars Go?

I had been fairly certain, that we had started with six cars, but we only arrived in Sheffield with four Class 153 trains.

I suspect that the trouble that delayed the train, concerned two cars and these were left on the naughty step or the end of Platform 6 in Liverpool Lime Street station.

Being Fair To East Midlands Railway

This service used to be run by a four-car formation of two-car Class 158 trains, but these have been causing trouble lately and they will be replaced by Class 170 trains cascaded from other operators.

But because of late arrivals of new trains the much better Class 170 trains haven’t arrived yet.

The driver, steward and other staff did a good job and I feel that the steward enjoyed it. No-one was abusive and stories were just exchanged, as we climbed across the Pennines in what by Sheffield was a very crowded train.

Class 153 trains may have been built as a stop-gap for short branch lines, but you couldn’t fault their performance.

Unless of course, one caused the delay at March, by expiring in a cloud of blue smoke.

Other Observations

These are other observations.

Scheduled Journey Times

On my journey the scheduled times were

  • Liverpool and Manchester Oxford Road – forty-seven minutes.
  • Liverpool and Sheffield – one hour and forty-eight minutes.
  • Liverpool and Nottingham – two hour and forty minutes.
  • Liverpool and Norwich – Five hours and twenty-seven minutes

The train considering the configuration, nearly achieved them.

It’s probably the motoring equivalent of doing the journey in a Morris Minor!

The Nine Stops Were Executed Perfectly

There were nine stops on my journey and eight took less than a minute, with Sheffield taking four, as the driver and crew changed.

A modern train like a Class 755 train, with fast acceleration and level boarding could probably save up to three minutes a time on each stop.

The Route Is A Genuine 75 mph Railway In Good Condition

I was checking the speed of the train on parts of the route and the driver had his motley crew at a steady 75 mph for long periods.

  • The train was riding well, indicating to me, that both trains and track were in reasonably good condition.
  • Note that 75 mph is the maximum speed of a Class 153 train.
  • The train recovered three minutes on the late departure from Liverpool.

I can see a faster train and improvements to the route, some of which are underway, could reduce the journey time by a few minutes.

Could Merseyrail’s New Class 777 Trains Work To The Bay Platform At Oxford Road?

Merseyrail’s new Class 777 trains will have the following performance.

  • A possible range of perhaps 40-50 miles on battery power.
  • An operating speed of 75 mph.
  • An acceleration rate of 1.1 m/sec², which is faster than a Class 153 or Class 170 train.
  • Fast stops due to regenerative braking, fast acceleration and level boarding.

As Liverpool Lime Street to Oxford Road is thirty four miles of which nine is electrified, I suspect that these new trains could extend Merseyrail’s Northern Line service from Hunts Cross to Manchester Oxford Road.

  • Two trains per hour (tph), but I’m sure four tph would transform the area.
  • I doubt any track modifications would be needed.

But would Liverpool and Manchester be able to sort out the local politics?

The Future Of The Liverpool And Norwich Service

This service will probably be spilt into two services.

  • Liverpool Lime Street and Derby, which could be run by TransPennine Express or Northern Trains.
  • Derby and Norwich, which would be run by East Midlands Railway.

As to the trains to be used, consider the following.

The Liverpool and Derby leg would probably need six trains, with the same number needed for Derby and Norwich, or twelve in total.

Currently, eleven or twelve is needed for the longer service.

Sections of the route like through Manchester and between Grantham and Peterborough are electrified.

There are even sections of route, where 125 mph running is possible.

Run reliably to an hourly frequency, I think that this service could attract passengers, especially, as it would serve Derby and extra stops like Ilkeston and Warrington West could be added.

This leads to the following trains being possibilities.

Class 802 trains – 125 mph bi-mode train of which TransPennine Express have 19 trains.

Class 185 trains – 100 mph diesel train of which TransPennine Express have 51 trains.

Class 804 trains – 125 mph bi-mode train of which East Midlands Railway have ordered 33 trains.

Class 755 trains – 100 mph diesel train of which Greater Anglia have 38 trains, which are based at Norwich.

Alstom Breeze hydrogen trains could be ideal for Liverpool and Derby.

Note.

  1. Greater Anglia and East Midlands Railway are both subsidiaries of Abellio.
  2. Developments of Class 755 trains could include battery and hydrogen versions.
  3. I suspect that 125 mph trains may be required for both legs, to maximise capacity on the East Coast Main Line and Midland Main Line.

January 29, 2020 Posted by | Transport | , , , , , , , , , , , , , , , | 5 Comments

No News On Hydrogen Trains For The Midland Main Line

In April 2019, I wrote Hydrogen Trains To Be Trialled On The Midland Main Line, which was based on an article on Railway Gazette that is entitled Bimode And Hydrogen Trains As Abellio Wins Next East Midlands Franchise.

I said this in my post.

Abellio will be taking over the franchise in August this year and although bi-mode trains were certain to be introduced in a couple of years, the trialling of hydrogen-powered trains is a surprise to me and possibly others.

This is all that is said in the article.

Abellio will also trial hydrogen fuel cell trains on the Midland Main Line.

It also says, that the new fleet will not be announced until the orders are finalised.

Nothing has been heard since about the hydrogen train trial for the Midland Main Line.

But there have been several related developments, that might have implications for the trial.

East Midlands Railway Has Ordered Hitachi Class 804 Trains For EMR InterCity Services

Class 804 trains are Hitachi’s latest offering, that are tailored for the Midland Main Line.

The trains will have a few differences to the current Class 800,/801/802 trains.

But will they be suitable for conversion to hydrogen power?

Consider.

  • The Hitachi trains have a comprehensivecomputer system, that looks at the train and sees what power sources are available and controls the train accordingly.
  • Trains have already been ordered in five, seven and nine-car lengths. I have read up to twelve-car trains are possible in normal operation. See Do Class 800/801/802 Trains Use Batteries For Regenerative Braking?
  • Hydrogen train designs, with a useful range of several hundred miles between refuelling, seem to need a hydrogen tank, that takes up at least half of a twenty metre long carriage.
  • The Hitachi train design has pantographs on the driver cars and can support diesel generator units in the intermediate cars, as it does in current trains.
  • The Japanese are researching hydrogen trains.
  • The five-car Class 802 trains have 2,100 kW of installed generator power.

I think that Hitachi’s engineers can build another carriage, with the following characteristics.

  • It could be based on a Motor Standard car.
  • The passenger seats and interior would be removed or redesigned in a shorter space.
  • Powered bogies would be as required.
  • It would contain a hydrogen tank to give sufficient range.
  • Appropriately-sized batteries and fuel-cells would be inside or under the vehicle.
  • Regenerative braking would help to recharge the batteries.
  • There would probably be no diesel generator unit.

There would need to be a walkway through the car. Stadler have shown this works in the Class 755 train.

A Hydrogen Power car like this would convert a five-car bi-mode diesel-electric train into a six-car hydrogen-electric hybrid train. Or they might just replace one Motor Standard car with the Hydrogen Power Car to create a five-car hydrogen-electric hybrid train, if the longer train would cause problems in the short platforms at St. Pancras.

  • The computer system would need to recognise the Hydrogen Power Car and control it accordingly. It would probably be very Plug-and-Play.
  • The weight of the train could probably be reduced by removing all diesel generator units.
  • The passenger experience would be better without diesel power.
  • The range away from the wires would probably be several hundred miles.

The drivers and other staff would probably not need massive retraining.

What Do I Mean By Appropriately-Sized Batteries And Fuel Cells?

I can’t be sure,, but I suspect the following rules and estimates hold.

  • The batteries must be large enough to more than hold the kinetic energy of a full five-car train, running at the full speed of 140 mph.
  • I estimate that the kinetic energy of the train,will be around 200 kWh, so with a contingency, perhaps battery capacity of between 400-500 kWh would be needed.
  • Currently, a 500 kWh battery would weigh five tonnes, which is of a similar weight to one of the diesel generator units, that are no longer needed.
  • In How Much Power Is Needed To Run A Train At 125 mph?, I estimated that the all-electric Class 801 train, needs 3.42 kWh per vehicle mile to maintain 125 mph. This means that travelling at 125 mph for an hour would consume around 2,000 kWh or an output of 2,000 kW from the fuel cell for the hour.
  • Note that 1 kg of hydrogen contains 33.33 kWh of usable energy, so the hydrogen to power the train for an hour at 125 mph, will weigh around sixty kilograms.

From my past experience in doing chemical reaction calculations in pressure vessels, I think it makes the concept feasible. After all, it’s not that different to Alstom’s Breeze.

I would assume, that the train manufacturers can do a full calculation, to a much more accurate level.

Applying The Concept To Other Hitachi Trains

Once proven, the concept could be applied to a large number of Hitachi bi-mode trains. I suspect too, that it could be applied to all other Hitachi A-train designs, that are in service or on order, all over the world.

In the UK, this includes Class 385, Class 395 and Class 80x trains.

Bombardier Have Said That They’re Not Interested In Hydrogen Power

But Electrostars and Aventras have the same Plug-and-Play characteristic as the Hitachi train.

I wouldn’t be surprised to find that Bombardier have a Hydrogen Power Car design for an Aventra. All that it needs is an order.

They could also probably convert a five-car Class 377 train to effectively a four-car train, with a Hydrogen Power Car in the middle. This would be ideal for the Uckfield Branch and the Marshlink Lines. I suspect it could be done to meet the timescale imposed by the transfer of the Class 171 trains to East Midlands Railway.

There must be an optimal point, where converting an electric multiple unit, is more affordable to convert to hydrogen, than to add just batteries.

But then everybody has been dithering about the Uckfield and Marshlink trains, since I started this blog!

Stadler Have Shown That a Gangway Through A Power Car Is Acceptable To Passengers In The UK

Stadler’s Class 755 trains seem to be operating without any complaints about the gangway between the two halves of the train.

Stadler Have Two Orders For Hydrogen-Powered Trains

These posts describe them.

Stadler also have a substantial order for a fleet of battery Flirt Akku in Schleswig Holstein and they are heavily involved in providing the rolling stock for Merseyrail and the South Wales Metro, where battery-powered trains are part of the solution.

It looks to me, that Stadler have got the technology to satisfy the battery and hydrogen train market.

The Driver’s View Of Stadler

It’s happened to me twice now; in the Netherlands and in the UK.

  • Both drivers have talked about hydrogen and Stadler’s trains with the engine in the middle.
  • They like the concept of the engine.
  • The English driver couldn’t wait to get his hands on the train, when he finished his conversion.
  • Both brought up the subject of hydrogen first, which made me think, that Stadler are telling drivers about it.

Or does driving a hydrogen-powered vehicle as your day job, score Greta points in the pub or club after work?

Could The Hydrogen Train On The Midland Main Line Be A Stadler?

Greater Anglia and East Midlands Railway are both controlled by Abellio or Dutch Railways.

In The Dutch Plan For Hydrogen, I laid out what the Dutch are doing to create a hydrogen-based economy in the North of the country.

Stadler are going to provide hydrogen-powered for the plan.

In addition.

  • Greater Anglia have bought a lot of Class 755 trains.
  • A lot of Lincolnshire and Norfolk is similar to the North of the Netherlands; flat and windy.
  • One of these trains with a hydrogen PowerPack, could be an ideal train for demonstrating hydrogen on rural routes like Peterborough and Doncaster via Lincoln.

But the promise was on the Midland Main Line?

Conclusion

Hydrogen trains seem to be taking off!

Even if there’s been no news about the trial on the Midland Main Line.

 

January 12, 2020 Posted by | Hydrogen, Transport | , , , , , , , , , | 3 Comments