Wind Resistance

A few weeks ago I met an intermodal with an arrowedge on it.  It was about 1/3 to 1/5 of the way back in the train.  I suspect it picked up a block at Rochelle, putting the arrowedge back in the train.

Jeff 

The UP is saving about 500 bucks in fuel for each Arrowedge they run on a train between Chicago and the Western ports on a round trip.  However if they are getting anything over a quarter a mile in revenue per container they would make more by shoving another load on the stack.  The fuel savings overall are not worth what they could make with another load in this case.  

I believe the fuel burn of a SD70 is around 190 gallons per hour in Run 8

About 2 or 3 months ago, I saw UP posted a news note about fuel saving of Arrowedge, stating that by employing Arrowedge can save about ~170 gallon(yes 170 gallon) of diesel when on a round-trip from LA to Chicago. I wonder is 170 gallon of diesel a good saving for a round-trip of a set intermodal containers train(about 2 or 3 hundrends of containers). 170 gallons seems a large number for we pumpimg gas at gas station. Interesting thing is that when I revisit this webpage last week, This quantified "saving of 170 gallon of a round-trip from LA to chicago" was removed from the original webpage that i saw..  Are UP and BYU doing some conspiracy  that we do not know of..   https://www.up.com/cs/groups/public/@uprr/@corprel/documents/up_pdf_nativedocs/pdf_utah_usguide.pdf

Oh the unintended consequences, best laid plans of mice and men,  are there other phrases that describe this all too common occurrence?????????

 I have read, the CIA when planning secret operations will consider the “blowback”.

 And then there is the famous Donald Rumsfeld quote.  “I know what I know, I know what I don’t know, but I don’t know what I don’t know.”

 And Shadow the Cats owner has as Paul H said, “The rest of the story”

 I had always taught in science class, “You can’t get something for nothing”.

So many times people will be impressed with a device that seems so powerful, but in reality, when all is considered, more input was needed than output gained.   Endmrw0206181148

A quick understanding of the physics can be found in the YouTube video by Feynman about how trains go around curves, and in Alan Wickens' paper on rail-wheel dynamics (from the mid-Sixties) that revolutionized high-speed guiding (the now-preserved HSFV being a dramatic illustration of the truth of his thoughts).

Up to that time, the general accepted wisdom for lightweight equipment, from Talgo forward through the early Train X proposals, involved independent stub axles on lightweight primary and secondary suspension, similar in general principle to the arrangement on Talgos that permits the aisle to go straight through the train.  I think they were working by analogy with automobiles, where there is no great issue if all four wheels turn at different speeds in high-speed curving.  But it turns out that this is NOT what is either wanted or desirable for high-speed railroad operation without flange contact.

In any case, the value of stub axles for container equipment, let alone stack equipment, is essentially nil.  Any economically valuable container width, regular ISO or special 'gap filler', is far more than the back-to-back dimensions of wheels in gauge, let alone any inboard beam or offset axle arrangement to support the inner stub.  So you can take as an insurmountable control dimension for the bottom deck gap the entire length of the bogie between wells, plus turning and articulation clearance and the thickness of the well forward bulkheads and any draft or clearance between inside of well and container at both ends.

We and many others played with the idea of adapting single steered axle sets between wells ... in the days of low-profile single-stack or van in well operation, keeping the load as low and as 'streamlined' as possible.  The problem, as you will quickly understand, is that you cannot possibly support the load of four 'container ends' on a single axle set within current HAL limits, and extending the limits even with modern head-hardened rail still leaves you with rail spalling and other wear problems that are metallurgy-limited, not technology-amenable.  So you need to leave room for two axles in there, plus for lowest floor some kind of bolster, and brake gear.  I have yet to find a solution better than that in most modern well cars, which is a Jacobs arrangement with the two well ends in ball-and-socket connection, and side bearings to a bolster in a three-piece arrangement.

That is why you either have to find something to close the unavoidable gaps over the trucks in question -- and stacking 53s on 48s has much of the desired effect for the intermediate gaps in the upper deck, if you have a consistent number of them, -- or figure out some way to prevent the effects of vortex formation and 'pumping' in the gaps.  No one who has ever proposed a system of smaller gap-filling containers between the outer ends of well sets has, to my knowledge, even gotten funding for regular-service-level testing, let alone marketing logistics, equipment management, and all the other things that made the marine-container revolution as we know it possible.

Now, the promise of the AirTabs and similar devices, if they actually turn out to work (and we have seen some claims even in this thread that they do not, at least in an appropriate railroad or trailer context) is that they produce airflow across the gaps that approximates laminar blocking flow against vortex induction even for strong quartering wind.  One 'catch' here is that any energy blocking a strong quartering wind must necessarily be drawn from the forward motion of the train, and I am not sure that the necessary structured laminar flow effects can be generated without themselves creating significant parasitic drag.  Therefore my conclusion that some kind of easily staged and struck gap-filling device that does not require special tools, and that can be stored in minimum space without weather damage, etc. etc. etc. is going to be the most effective solution.  Note that I immediately invoke the first law of consulting:  "The best solution to your issue is not necessarily a good solution".  And the solution represented by the 'null hypothesis' -- leaving the gaps open and using fuel to overcome the drag -- may represent the bottom-line least 'costly' alternative for a given railroad management.  (But just think what could be done with the amount thrown down on the Arrowedge boondoggle! )

Overmod

Stub axles are the wrong answer to a question no one aware of the physics involved would have asked.

Overmod

My solution is to adapt the modular air dunnage system to work between adjacent container loads, giving the effect of a very light full-width diaphragm engaged into the end twistlock castings.  This does have the effect of increasing tipover force for crosswinds, but the approaches discussed in the cited paper would likely serve to assist train handling in such circumstances.

Good for windage.  Works on existing equipment.  Very hard to implement for a bunch of reasons, some practical, some railroad culture.

Reducing the gap has the very real advantage of increasing terminal capacity.  That's worth big bucks, on top of fuel savings.  

Roadrailer was the right answer to the wrong question.  Now we need the right answer to the right question.  The industry just has to be a bit clever and forward thinking.

zugmann

 

BaltACD

Wind Derailment on CSX - Susquehanna River Bridge http://www.baltimoresun.com/news/weather/bs-md-csx-20180303-story.html#nt=oft12aH-1gp2 

No wind detectors on that bridge?

No.  I understand the crew had requested to hold at West Aikin until wind subsided (MD DOT had the I-95 and US 40 bridges closed at the time - all 3 bridges are within eyesight of each other) and crew was instructed by senior division management to proceed.  The curse of EHH strikes again.

Well the insurance companies are being to scream back at the regulations imposed upon us. Why those trailer skirts that CARB mandated well there is enough actuarial data now that proves those skirts have increased the roll over risk of a class 8 OTR truck 40% over ones without on the same roads and conditions.  They are jacking rates up more on carriers with them.  

BaltACD

Wind Derailment on CSX - Susquehanna River Bridge http://www.baltimoresun.com/news/weather/bs-md-csx-20180303-story.html#nt=oft12aH-1gp2

No wind detectors on that bridge?

Wind Derailment on CSX - Susquehanna River Bridge

http://www.baltimoresun.com/news/weather/bs-md-csx-20180303-story.html#nt=oft12aH-1gp2

I will give a more complete answer later.

Three-piece trucks are not a current issue; they should in fact work just fine with depressed-center bolsters if there is some reason to decrease ride height.  They have considerable advantages and only a few drawbacks in even fast intermodal service.  Pants or shrouds on the trucks have been recognized as 'not really worth it' even for much faster trains that are more horsepower-limited.

Stub axles are the wrong answer to a question no one aware of the physics involved would have asked.  If you don't get the answer from Feynman you can get it from Wickens.  Far less than no reason to abandon current wheel set and bearing provision.

My solution is to adapt the modular air dunnage system to work between adjacent container loads, giving the effect of a very light full-width diaphragm engaged into the end twistlock castings.  This does have the effect of increasing tipover force for crosswinds, but the approaches discussed in the cited paper would likely serve to assist train handling in such circumstances.

Much discussion over using small containers on special mountings to 'bridge' the monkey decks at the ends of articulated well sets.  Some of the patents were very carefully well thought out.  None of them have any particular chance of success, for reasons the intermodal guys here comprehend pretty well.

I would be interested to see a CFD analysis of empty centerbeams with and without funky oval holes in beam or bulkheads, and the percentage of retardation caused by the open tops of hoppers/Bethgons vs. the drag from the ribs and intercar spacing.

jeffhergert

I have no doubt that during severe wind conditions an empty coal train burns as much, or more fuel as a load.  I've had empties where the speed picks up by about 5mph when you go through places with wind breaks, such as towns.  Back out in the relative open farm land, speed drops back off by about 5mph.  Stack and autorack trains are slowed by high winds too.  I doubt the arrowedge does much good in a crosswind.  Heck, I doubt it does any good at all. Jeff

So, if you were designed a "next generation" intermodal car, what would it look like?

- How to minimize gap?  Get rid of 3 piece trucks?  Stub axles?

- air flow around and under car?

- light weight?  Would it necessarily have to meet interchange standard?  Could the use of multiple DPUs reduce buff/draft requirements?

http://www.airflowsciences.com/sites/default/files/docs/Rail_Train_Aerodynamics.pdf

As saw in paper, developed by James C. Paul,

 Gallons of Fuel Consumed per 1,000 miles = K (0.0015 W + 0.00256 Sd V2 + C W) 

where: K = Fuel consumed per distance traveled per unit of tractive resistance = 0.2038 gallons/1,000 miles/lbf Sd = Consist Drag Area (ft2 ) V = Train Speed (miles/hour) W = Consist Weight (lbf) C = Hill Factor = 0.0 for level routes and 0.0007 for hilly routes 

Jame Paul has Wind Tunnel and CFD result of relationship between Gap length and Fuel saving(from Drag reduction).

Adding smooth sides to the well car improves fuel economy on level routes by 7.3% for low speeds up to 12% for high speeds. For hilly routes, fuel economy improvements vary from 5% at low speeds to 6% at high speeds. Reducing the inter-car gap also provides significant improvements in fuel economy. For level routes, reducing the inter-car gap from 61.5 inches to 47 inches reduces fuel usage by 5% at low speeds and 8% at high speeds. For hilly routes this reduction in gap distance improves fuel economy by 4% at low speeds and 7% at high speeds. 

Well, as Leonardo da Vinci said at 18, when you find out the 'authorities' on a particular issue (in his case Aristotle on what we now call gravitational acceleration) are demonstrably not just in error but flat wrong, you have to take the course of learning about the subject 'from all angles' yourself until satisfied you understand the actual 'thing as it is'.  Welcome to one of the right parts of the Western tradition.

What I cautiously advise you NOT to do is start cussing UP and the kids in Utah as 'liars' just because they haven't quite done their homework.  Science works a funny way - find a better physical model of what either Arrowedge does or doesn't do; go into Research Reports in the e-library and see what you find; model the interaction of a train with quartering wind at different speed or angle; look at a recent thread describing centerbeams to see why cars with lots of lightening holes are harder to pull than those without -- and all of them much harder to pull than several good engineers here say they would have expected until they found out for themselves.

It's also possible for designers to think, with a clear conscience, that their bold new theory of aerodynamic drag reduction for railroad trains is correct.  Here again I am reminded of Angus Sinclair commenting on the little arrows that show steam flow in patent drawings.  Since steam doesn't know how to read, sometimes it flows a decidedly different (and less lucrative to the patent holder) way.  Shakespeare had a character who proudly thundered his knowledge: "I can call spirits from the vasty deep!" -- but another character who promptly stuck a pin in it by asking quietly "but do they answer?"  The criterion here is absolute drag reduction, measured at the power drawbar, under the weighted average of all the conditions encountered over actual trips.  Plus the cost of building, maintaining, handling and perhaps being inconvenienced by any special equipment.

Very knowledgeable and skilled people have been studying and experimenting with more efficient 'front ends' for steam locomotives.  A problem is that the 'default' design is not necessarily the most thermodynamically effective; the actual equipment should be capable of 'automatic action' without needing adjustments or wacky moving parts; it shouldn't produce 'crazy high' superheat in some of the elements at high speed; it should deal effectively with 'sparks' and soot in the combustion gas, etc.  When even spectacular math produces results that don't do those things, both the design and the design principle run the risk of being exposed as failures at best, and snake oil far from the worst.

http://capstone.byu.edu/previous-projects/arrowedge-rear-fairing-extension

http://capstone.byu.edu/previous-projects/arrowedge-intermodal-fairing

Union Pacific develped this Arrowedge ~10 years, claiming that taking care of the frontal impact wind resisatnce at the first car will be enough at first car. The aerodynamic drag of Hundreds of Gaps between cars is not big enough to worry about(possibly platoooning). However, this Arrowedge Extension Fairing said that closing the gap after Arrowedge is important and good. Can someone tell why a gap right after Arrowedge is important, but the Hundreds of Gap afterward is not important.. Also there are 2 types of Gap, one is ~3.5 meter(articulate car), another is ~7 meter(independent car). So question is, is inter-car gap an important aerodynamic drag or not? If no much drag, ok, close of story. If yes, what is the Quantitative relationship between gap sizes(3.5 and 7 meter) and aerodyanamic drag?  We saw UP and BYU can not tell this ultimate point Clearly, for ~10 years..

Since UP bought Railex and the order of the day is G-55, many intermodal trains now have blocks of reefers (sometimes more reefers than stacks) and/or autoracks.  I saw an intermodal with a block of reefers behind the power and in front of the first stack car.  That first stack car had an arrowedge on it.

I have no doubt that during severe wind conditions an empty coal train burns as much, or more fuel as a load.  I've had empties where the speed picks up by about 5mph when you go through places with wind breaks, such as towns.  Back out in the relative open farm land, speed drops back off by about 5mph.  Stack and autorack trains are slowed by high winds too.  I doubt the arrowedge does much good in a crosswind.  Heck, I doubt it does any good at all.

Jeff

CMStPnP

Wasn't part of the purpose of the steam streamlining to channel the coal smoke from the stack?    Didn't it work in that respect?

According to Kratville, not very well.  In my relatively extensive research into 'smoke lifting devices' I never found any skyline-casing device that actually worked as intended, and some (like the headlight on the superb NZR K-class 4-8-4s) that caused more problem than they solved.

In any case, if you think about it a moment all these devices were meant to deflect air powerfully in a direction it didn't want to go.  That will tell you they induced more drag than proper streamlining would, meaning they would be dissipating more horsepower -- increasingly more horsepower as the engine started to produce relatively less and less -- at speed.

I am not saying that all streamlining was purely 'tin' for marketing purposes; certainly the engines under the streamlining were two of UP's best up to that point, and were regularly run well into the speed range where practical streamlining begins to show value.  But I don't think either shroud was particularly more aerodynamic than Kantola's for 5344, which I think 'peaked' at saving about 300hp.  That's not going to translate into much overall fuel savings, and full shrouding could be incredibly heavy (remember that 3765 was to have gotten a Mae West shroud, but even the skirting would have made her too heavy and was never applied).  So I think most of the parallels between the Arrowedge effort and the two 'Steamliners' can be drawn effectively.

Overmod

I doubt it makes any more sense than UP steam streamlining did

Wasn't part of the purpose of the steam streamlining to channel the coal smoke from the stack?    Didn't it work in that respect?

Part of the problem, I think, is that neither the original Arrowedge or its college reboot really seem to have a grasp of the aerodynamics around loaded stacks.  The reason for the 'crash' was that the device experienced aerodynamic lift but was not twistlocked down; that was not too bad in itself until you started looking back along the top of the train at the effect of 'enough' disturbed air to raise the back of the wedge with that much force.

One major mode of resistance (which I originally saw modeled for TOFC consists on those delightful ATSF Fuel Foilers) is the train making speed into a quartering wind, so that the resultant of slipstream and wind is incident on all the 'fronts' in the train and there is minimal effect from 'vacuum' or drafting pressure reduction from the trailer(s) ahead.  The 'correct' answer here is to provide the equivalent of full-width diaphragms between trailer bodies or containers; you still have the lateral-pressure and drag increase on the surface, but not all those square feet encountering overpressure.

It's comparatively simple to arrange a modification of modular dunnage that has frames that twistlock to the 'front' and 'back' of a container with an internally -reinforced inflatable cell given a tough outside surface.  'Theoretically' these could be easily deployed as the train is loaded, in near-parallel with crane lifts so any critical-path extension is relatively minimal, and the deflated device easily rides on one container or the other during unloading and can even, in a pinch, be roaded.

You don't see these marketed, which should tell you a bit about relative economics: fuel surcharges are a whole lot easier, and about as bottom-line effective, as streamlining savings.  And when 'real' streamlining involves far more than flow-smoothing the front of the train consist over the power, it's relatively easy to see why not much has been tried up to now.

Something that hasn't been mentioned here is the extreme low tare weight of modern well-car equipment.  That has proven a source of considerable saving in intermodal operation.

Anj intersting topic for a Thread!  After reading it back to the original poster's Thread.  And not being an academic but just a casual observer. 

The main issue in my mind, boils down to a #1 area of interest, ultimately, that of dwell time for the train? The gathering of equipment and then the assembly of the train; followed by the actual loading, confirmation of various administrative functions for that train. Lastly, ultimate departure to the next point in the life of that train.   Basicly TIME !  Everything else is part of the academic excercise to extract as much revenue as possible from the specific train.

The aerodynamics, fuel consumption x number of units needed to move the train over the railroad. As with long evolved railroad practices; trains may be 'solid' to the final destination, or they may be 'blocked' to facilitate delivery as blocked to those points needed by the railroad.  Each adderd enhancement may add to the amount of dwell time at the TERMINAL.  Balance that with whatever fuel savings can be developed within the parameters of a specific railroad operation. And at some point fit in the practical benefits of aerodynamics and that amount of savings. Each step in the process becomes a balance of trade-offs. IMO.

I am sure others here are more competent to discuss the dollar amounts, and the academic of those points.   Before this subject can be adapted in the practrical, real world  of today's railroading. My guess is the 'systems' will have to be re-engineered from the very concept to its realistic applications.

Remember, the Thread and its poltos, some time back whe one of UPRR's "Arrowedge" devices met its' demise on a low highway bridge in Wisconsin? Apparently, left on a train as it was reworked and sent out on an un-tested routing?  THAST was probably, pretty expensive, and problematic for UPR?

THe gaps between well cars is not uniform and seems to vary with each reloading(?) 20' TEU's (in pairs) 40' cans (stacked) 45' cans (stacked on top of shorter cans.) 53' cans stacked on whatever else is available to be stacked on?).

Chemical tanks, generally, singled out in the wells (without stacking them/Haz-Mat regs?) 

TOFC Trains with their trailers ( aerodynamic enhacements are loaded according to the 5th wheels availibility/ trailer may be loaded backwards facing, in which case, they are not helpful to the over all areodynamics within the train). 

The original posting of the PDF and its research is just that, another academic exercise with interesting results. Practical? Who knows at this stage of the game. It seems to come down to the availability of 'seed money' from Uncle Sam.                  Or local politicians legislating 'feel good' laws; to garner votes from their cnstituants. Enhancements, that ultimately, wind up costing the consumer in the cost to get goods to the points of sale?

 Cynical, you bet I am!  The following link shows some insight:Linked @ https://www.thebalance.com/what-is-the-value-of-a-dollar-today-3306105

The reality is that UP won't observe even a fraction of that reduction in fuel burn, as it only applies to reasonably frontal resistance on the relatively few train-miles run with them.  I have not seen actual dynamometric reference to the change in resistance of version 2 over version 1, but I'm of the opinion neither one does much practically.

But you are using the wrong criterion even for fuel burn by omitting the fuel consumed in picking and placing these devices on consists (no GHA being available even with expedient prayer to do that for you) or the additional non revenue tare weight that must now be hauled up any grades.  Or the costs involved in fabricating the things (this being a major point in going to version 2) and keeping them around in active yards in sufficient numbers and in expedient places to put on consists.

When you actually cost this out, I doubt it makes any more sense than UP steam streamlining did -- the money is in the marketing appeal and the perception of the unwary. Pity, because I liked the look of version 1's RV-like shape (and I don't mean recreational vehicle, at least not in the Bago sense...)

Dakguy201

I am wondering that since the railroad finds the efficiency of the Arrowedge sufficient to surrender a revenue producing place on the train, would it also make sense to ship an empty container on any car that would otherwise be a single stack?

Well just don't put an empty container on top, as they've been known to blow off on Sherman Hill, where the wind rages.

rossi

I saw UP put some extension fairing at the trail-side of Arrowedge+  some Arrowege has put Airtab at trail. I think Airtab is a stupid idea. The extension fairing probably has a some limited saving(+if diluted with 100's of cars). Please comment.   https://www.youtube.com/watch?v=hMsAdOTl2Mg                https://www.youtube.com/watch?v=4GoHzNKrDy0                http://capstone.byu.edu/previous-projects/arrowedge-rear-fairing-extension 

While I tend to agree that UP's wedge has limited if any benefit; the reality is that if UP can demonstrate the fuel savings are 1/10th of a per cent - with the amount of fuel that UP uses that adds up to real money for them.

I saw UP put some extension fairing at the trail-side of Arrowedge+  some Arrowege has put Airtab at trail. I think Airtab is a stupid idea. The extension fairing probably has a some limited saving(+if diluted with 100's of cars). Please comment.   https://www.youtube .com/watch?v=hMsAdOTl2Mg                https://www.youtube.com/watch?v=4GoHzNKrDy0                http://capstone.byu.edu/previous-projects/arrowedge-rear-fairing-extension

re:Platooning

A truck driver friend said, "We used to call it drafting, the cops called it following toooo close, and now that there's  a computer involved, it's safe and legal.  It might be good, but as usual, it's probably not for me." 

rossi

I have read a Taiwanense professor's PhD thesis at Uof Illinois and AAR (funded by BNSF and CN), stating that the combined aerodyanimc drag increases linearly proportional to Container Gap Size, from 1 foot and saturates at ~12 feet. After 12 feets, the Drag starts all over again like a FIRST Frontal Drag. I also read somewhere(youtube or somewhere?) that Mike Iden of Union Pacifioc complains that the 3/5 articulated container wagons have a Gap of ~11 feet. I do not know the sizes of Independent Car/Wagon. I think they are ~20 to 25 feet length.. I think the aerodynamic drag are pretty much independent each other. Not sure much paltooning works here...