The Anonymous Widower

President Maduro Of Venezuela

Seeing President Maduro of Venezuela standing there in his extravagant suit with a multi-coloured sash, he looked so like one of the comic creations of Sacha Baron Cohen.

Now, I’m afraid every time I hear his name mentioned I laugh!

 

August 5, 2018 Posted by | News, World | , , , | Leave a comment

What Is The Battery Size On A Tri-Mode Stadler Flirt?

The power-pack in the middle of a Tri-Mode Stadler Flirt, would appear to have four slots, each of which could take.

  • A V8 16-litre Deutz diesel that can produce 478 kW and weighs 1.3 tonnes.
  • A battery of about 120 kWh, which would probably weigh about 1.2 tonnes.

Would future versions of these trains accept a hydrogen fuel cell?

Note that, I estimated the battery size, by using typical battery energy densities for a battery of similar weight and physical size to the diesel engine.

August 5, 2018 Posted by | Travel | , | 1 Comment

Would Electrically-Driven Trains Benefit From Batteries To Handle Regenerative Braking?

There are two basic types of electrically-driven trains.

Electric trains, which include electrical multiple units and trains hauled by electric locomotives like the InterCity 225.

Diesel-electric trains, with include multiple units like Voyagers and the InterCity 125.

Regenerative Braking

In an electrically-driven train, the traction motors can be turned into generators to slow the train, by turning the train’s kinetic energy into electricity.

Many electric trains can do this and the generated electricity is returned through the electrification system, so that it can power other trains nearby.

This all sounds fine and dandy, but there is the disadvantage that all the electrification system must be able to handle the reverse currents, which increases the capital cost of the electrification.

Batteries For Regenerative Braking

Fitting batteries to a train, to handle the electricity that is generated by regenerative braking is an alternative.

A Station Stop

Suppose a four-car train that weighs 200 tonnes is travelling at 125 mph and needs to stop at a station.

My example train would according to Omni’s Kinetic Energy Calculator would have a kinetic energy of 86.7 kWh.

To put that amount of energy into context, the traction battery in a New Routemaster bus is 55 kWh.

So if a battery of this size was put into each car, there is more than enough capacity to store the energy of the train, when it stops at a station.

When the train leaves the station, a proportion of this energy can be used to accelerate the train back to 125 mph.

As regenerative braking is perhaps only eighty percent efficient at present, additional energy will need to be provided.

But even with btoday’s primitive batteries and less-than-efficient traction motors, there are still substantial energy savings to be had.

Hitachi Class 800/801/802 Trains

In Do Class 800/801/802 Trains Use Batteries For Regenerative Braking?, I looked at the question in the title.

I found this document on the Hitachi Rail web site, which is entitled Development of Class 800/801 High-speed Rolling Stock for UK Intercity Express Programme.

It was written in 2013 and I suspect every train designer has read it, as it gives a deep insight into the design of the trains.

The document provides this schematic of the traction system.

Note

  1. BC which is described as battery charger.
  2. The battery size is not disclosed.
  3. The APS supplies the hotel power for the train in two different voltages.
  4. Can the APS with the battery supply power to the Drive Converter?

After a lot of reasoning, I came to this conclusion.

I will be very surprised if Class 800/801/802 trains don’t have batteries.

Looking at the schematic of the electrical system, the energy captured will at least be used for hotel power on the train.

Hitachi have not said, if the batteries on the Class 800/801/802 trains can be used for traction purposes.

Storing the regenerative energy in a battery can be used for one of two purposes.

Hotel Power

Hitachi’s Class 800 trains certainly use the electricity in the battery to power the hotel functions of the train like air-conditioning, doors, lights, power-sockets, toilets and wi-fi.

In a diesel-electric train, this could give benefits.

  • The engines generally won’t need to run in a station to provide hotel power.
  • Less fuel will need to be expended to provide hotel power.
  • If say the train has to halt perhaps because of a signalling or track fault, hotel power can be provided without running the engines.
  • If batteries are supplying the hotel power, the train may have more power for traction.

Overall, the diesel-electric train would be more efficient and would emit less carbon dioxide and pollutants.

Traction Power

There is no engineering reason, why the energy in the battery can’t be used to actually move the train.

But to implement it, could be complicated and expensive on an existing train.

Some Worked Examples

I’ll look at a few examples.

InterCity 125

The iconic InterCity 125s are unique, in that they are impossible to scrap. Just as they seem to approaching the end of their life, a devious engineer or marketing man comes up with a plan to keep them running.

 

As I write this, Great Western Railway and Abellio ScotRail are testing short-formation InterCity 125s and training drivers for services in the South West of England and Scotland. Both train operating companies appreciate the marketing advantages of Terry Miller‘s world-famous train, that was built as a stop-gap, after the failure of the Advanced Passenger Train.

So what size of battery would need to be fitted to each locomotive to handle the braking energy of a short-formation InterCity 125 with four passenger cars?

Consider.

  • Each Class 43 locomotive weighs 70.25 tonnes.
  • Each Mark 3 coach weighs 33.60 tonnes.
  • An eight car InterCity 125 can carry about 500 passengers.
  • I will assume that a four-car InterCity 125 can carry 250 passengers.
  • If each passenger weighs 90 Kg with all their bikes, buggies and baggage, that adds up to 22.50 tonnes.

This gives a total train weight of 297.40 tonnes.

Calculating the kinetic energy using Omni’s Kinetic Energy Calculator for various speeds gives.

  • 50 mph – 20.6 kWh
  • 75 mph – 46.4 kWh
  • 90 mph – 66.9 kWh
  • 100 mph – 82.5 kWh

A fifty kWh battery in each locomotive would be able to handle the braking energy of the train.

The only problem, is that Class 43 locomotives have DC traction motors, no regenerative braking and air brakes.

But if any operator or rolling stock owner were bonkers enough to fit a new traction system, a diesel/electric/battery Class 43 locomotive is possible for a four-car InterCity 125.

This page on the Hitachi web site is entitled V-TRAIN 2.

Hitachi used a Class 43 power car to prove that diesel/electric/battery trains were feasible, before getting the order for the Class 800 trains.

So fitting batteries to Class 43 locomotives has been done before!

The simplest thing to do would be to use the batteries to provide hotel power for the train.

Class 375 Train

In this exercise, I shall consider a Class 375/6 train, with the following characteristics.

  • Four cars
  • Three cars are motored.
  • Regenerative braking
  • A weight of 173.6 tonnes.
  • A capacity of 236 seated passengers
  • An operating speed of 100 mph.

I will now go through my standard train kinetic energy calculation.

  • I will assume three hundred passengers including standees.
  • If each passenger weighs 90 Kg with all their bikes, buggies and baggage, that adds up to 27 tonnes.

This gives a total train weight of 200.60 tonnes.

Calculating the kinetic energy using Omni’s Kinetic Energy Calculator for various speeds gives.

  • 50 mph – 13.9 kWh
  • 80 mph – 35.6 kWh
  • 100 mph – 55.7 kWh

It would appear that adding batteries to a Class 375 train would not involve large capacity batteries, especially if one was added to each of the three cars with motors.

As a Control Engineer by training, blending battery and electrification power could run the train more efficiently.

Probably naively on my part, I suspect that using batteries on Class 375 trains to handle regenerative braking, would be one of the easier installations.

Other Electrostars

All Electrostars are fairly similar, so if Class 375 trains could be updated, then I wouldn’t be surprised if all could.

InterCity 225

It looks like InterCity 225 trains will be used between London and Blackpool by Alliance Rail Holdings.

Other commentators have suggested that shortened sets run on the Midland Main Line between a diesel locomotive and a Driving Van Trailer (DVT) or two Class 43 locomotives.

I shall do the energy calculation for a five-car InterCity 225.

  • A Class 91 locomotive weighs 81.5 tonnes.
  • A Mark 4 coach weighs between 40 and 43.5 tonnes.
  • A nine-car InterCity 225 seats 535 passengers.
  • I will assume that a five-car InterCity 225 will seat around 300 passengers.
  • I will assume each passenger weighs 90 Kg. with all their baggage, bikes and buggies.
  • A DVT weighs 42.7 tonnes.

For a current nine-car train this gives the following.

  • The empty train weight is almost exactly 500 tonnes.
  • The passengers weigh 48 tonnes.
  • This gives a total weight of 548 tonnes.

At 125 mph, the nine-car InterCity 225 has a kinetic energy of 238 kWh.

For a proposed five-car train this gives the following.

  • The empty train weight is almost exactly 333 tonnes.
  • The passengers weigh 27 tonnes.
  • This gives a total weight of 360 tonnes.

At 125 mph, the five-car InterCity 225 has a kinetic energy of 156 kWh.

Reduce the speed to 110 mph and the kinetic energy drops to 121 kWh.

I suspect that using current technologies, there is not enough space in a Class 91 locomotive for the batteries.

Perhaps a short section of the coach next to the engine could be converted to hold a large enough battery.

Five Mark 4 Coaches And Two Class 43 Locomotives

This has been suggested in Modern Railways by Ian Walmsley and I wrote about it in Midland Mark 4.

Consider.

  • A Class 43 locomotive weighs 70.25 tonnes.
  • A Mark 4 coach weighs between 40 and 43.5 tonnes.
  • A nine-car InterCity 225 seats 535 passengers.
  • I will assume that a five-car InterCity 225 will seat around 300 passengers.

This gives the following.

  • The empty train weight is 349 tonnes
  • The passengers weigh 27 tonnes
  • The train weight is 376 tonnes.

At 125 mph this train would have a kinetic energy of 163 kWh.

I’m sure that it would be possible to put a 100 kWh battery in the space behind the engine of a Class 43 locomotive, so I suspect that all the engineering solutions exist to create a train with the following characteristics.

  • Two Class 43 locomotives with new traction motors to enable regenerative braking and a 100 kWh battery.
  • Five Mark 4 coaches meeting all the regulations.
  • The batteries would provide hotel power for the train.
  • 125 mph operating speed.

It may be a fantasy, as the economics might not stack up.

Five Mark 4 Coaches, A Driving Van Trailer And A Stadler UKLight Locomotive

I wrote about this combination in Five Mark 4 Coaches, A Driving Van Trailer And A Stadler UKLight Locomotive.

I came to this conclusion.

Using the Mark 4 coaches or new Mark 5A coaches with a new 125 mph diesel/electric/battery hybrid Stadler UKLight locomotive could create an efficient tri-mode train for the UK rail network.

The concept would have lots of worldwide applications in countries that like the UK, are  only partially electrified.

The concept or something like it, has possibilities.

Voyagers

In the July 2018 Edition of Modern Railways, there is an article entitled Bi-Mode Aventra Details Revealed.

A lot of the article takes the form of reporting an interview with Des McKeon, who is Bombardier’s Commercial |Director and Global Head of Regional and Intercity.

This is a paragraph.

He also confirmed Bombardier is examining the option of fitting batteries to Voyager DEMUs for use in stations.

The Voyager family of trains has three members.

The trains are diesel-electric and I explore the possibility of using batteries in these trains in Have Bombardier Got A Cunning Plan For Voyagers?.

I felt is was a good plan.

Conclusion

In answer to the question, that I posed in the title of this post, I feel that handling regenerative braking in batteries on the train could be of benefit.

 

 

 

 

 

 

 

 

 

 

 

August 5, 2018 Posted by | Travel | , , , | 1 Comment

Five Mark 4 Coaches, A Driving Van Trailer And A Stadler UKLight Locomotive

In writing Would Electrically-Driven Trains Benefit From Batteries To Handle Regenerative Braking?, I started to analyse the mathetics and possibilities of a train with the following formation.

The sub-section got too large and important so I decided to write it as a separate post.

I like the Class 68 locomotive, as it looks professional and seems to do all asked of it.

So what would be the kinetic energy of a formation of five Mark 4 coaches, between a DVT and a Class 68 Locomotive?

  • The five Mark 4 coaches would weigh 209 tonnes.
  • The Class 68 locomotive weighs 85 tonnes.
  • The DVT weighs 42.7 tonnes
  • I will assume that a five cars will seat around 300 passengers.
  • The passengers weigh 27 tonnes, if you assume each weighs 90 Kg, with baggage, bikes and buggies.
  • The train weight is 363.7 tonnes.

At 100 mph, which is the maximum speed of the Class 68 locomotive, the Omni Kinetic Energy Calculator gives the kinetic energy of the train as 100 kWh.

I doubt there’s the space to squeeze a 100 kWh of battery into a Class 68 locomotive to handle the regenerative braking of the locomotive, but I do believe that a locomotive can be built with the following specification.

  • Enough diesel power to pull perhaps five or six Mark 4 coaches and a DVT at 125 mph.
  • Ability to use both 25 KVAC and 750 VDC electrification.
  • Battery to handle regenerative braking.
  • As the Class 88 electro-diesel locomotive, which is around the same weight as a Class 68 locomotive, I suspect the proposed locomotive would be a bit heavier at perhaps 95 tonnes.

This train would have a kinetic energy of 160 kWh at 125 mph.

Consider.

  • If the locomotive could have a 200 kWh battery, it could harvest all the regenerative braking energy.
  • Accelerating the train to cruising speed uses most energy.
  • Running at a constant high speed, would conserve the kinetic energy in the train.
  • Stadler, who manufacture the Class 68 and 88 locomotives are going to supply a diesel/electric/battery version of the Class 755 train, for the South Wales Metro. In What Is The Battery Size On A Tri-Mode Stadler Flirt?, I estimated the battery size is about 120 kWh.
  • The Class 68 and 88 locomotives are members of Stadler’s Eurolight family, which are designed for a 125 mph capability with passenger trains.
  • I don’t believe the UK is the only country looking for an efficient locomotive to haul short rakes of coaches at 125 mph, on partially-electrified lines.

It should also be noted, that to pull heavy freight trains, the Class 88 locomotive has a 700 kW Caterpillar C27 diesel that weighs over six tonnes, whereas 200 kWh of battery, would weigh about two tonnes. I believe that a smaller diesel engine might allow space for a large enough battery and still be able to sustain the 125 mph cruise.

Stadler have the technology and I wonder, if they can produce a locomotive to fill the market niche!

In HS2 To Kick Off Sheffield Wiring, I reported on the news that the Northern section of the Midland Main Line between Clay Cross and Sheffield will be electrified.

This would greatly improve the performance of diesel/electric/battery hybrid trains between London and Sheffield.

  • Between London and Kettering, the trains would be electrically-powered.
  • Between Kettering and Clay Cross, they would use a mixture of diesel and battery operation.
  • Between Clay Cross and Sheffield, the trains would be electrically-powered.

Note.

  1. Going North, trains would pass Kettering with a full battery.
  2. Going South, trains would pass Clay Cross with a full battery.
  3. Regenerative braking at stops between Kettering and Clay Cross would help recharge the batteries.
  4. The diesel engine would be sized to keep the train cruising at 125 mph on the gentle Midland Main Line and back up the acceleration needed after stops.

It would be a faster and very electrically-efficient journey, with a large reduction in the use of diesel power.

The locomotive would also have other uses in the UK.

  • TransPennine services, where they could surely replace the Class 68 locomotives, that will haul Mark 5A coaches between Liverpool and Scarborough and Manchester Airport and Middlesborough.
  • Between London and Holyhead
  • Waterloo to Exeter via Basingstoke and Salisbury.
  • Marylebone to Birmingham via the Chiltern Main Line, if the two ends were to be electrified.
  • Services on the East West Rail Link.
  • Between Norwich and Liverpool
  • CrossCountry services.

Note.

  1. Services could use a rake of Mark 4 coaches and a DVT or a rake of new Mark 5A coaches.
  2. If more electrification is installed, the trains would not need to be changed, but would just become more efficient.
  3. The competition would be Bombardier’s proposed 125 mph bi-mode Aventra with batteries, that I wrote about in Bombardier Bi-Mode Aventra To Feature Battery Power.

And that is just the UK!

Conclusion

Using the Mark 4 coaches or new Mark 5A coaches with a new 125 mph diesel/electric/battery hybrid Stadler UKLight locomotive could create an efficient tri-mode train for the UK rail network.

The concept would have lots of worldwide applications in countries that like the UK, are only partially electrified.

 

 

August 5, 2018 Posted by | Travel | , , , , , | 1 Comment

HS2 To Kick Off Sheffield Wiring

The title of this post is the same as that of a small article in the August 2018 Edition of Modern Railways.

This is the first paragraph.

HS2 Ltd is to begin preparatory works for electrification of the Midland Main Line between Clay Cross and Sheffield

This will mean that the current Midland Main Line will be electrified at both ends, which will surely make it easier to design new trains for the line.

August 5, 2018 Posted by | Travel | , , | 1 Comment

Canada Envisions Small Nuclear Reactors Producing Power And Hydrogen In Remote Towns

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

The concept is you put small modular nuclear reactors of around 300 MW in a remote town or industrial site to provide electrical power, alongside wind and solar

Any excess power will be used to create hydrogen to power transport like vehicles and trains, so no power is wasted.

These reactors will be built in a factory and transported to site.

It may seem to be fantastical thinking, but I believe small modular reactors are a viable concept and used with hydrogen in remote locations could be application, that gets them started and acceptable.

Two years ago I wrote Small Modular Nuclear Reactors.

My views haven’t changed, except that adding the hydrogen generation improves the reasons to build them.

August 5, 2018 Posted by | World | | Leave a comment