#4 vs #5 turnout

To distill the original question to its essential essence:

I handlay all of my specialwork, so I'm certain that my #4 turnouts (on my end-of-the-coal-hauler module, built in 1980) and my #5 turnouts (in the hidden staging yards at Nonomura, built within the last decade) are built to the proper dimensions.

That said, one of my long-wheelbase 2-Co+Co-2 EF18 or EF58 class juice jacks can slither through a #5.  Trying to force it through the curved route of a #4 will put it on the ground, every time.

Why?  Those motors require an honest 24 inch (610mm) radius to operate.  The closure rail of a #4 turnout has a radius too tight for the long rigid wheelbase.  The axle under the center of the carbody gets pinched over the rails on whichever truck hits the tight spot first.

Chuck (Modeling Central Japan in September, 1964)

I just use the printable turnout plans from fast tracks, cut ties to match, build the frog with the frog jig, points with point jig and eyeball the rest.

after re-reading Ed's post, I realize this is what he was describing

the discrepancy between what Randy reported, 9.46 deg or 9d 27", and the other value of 9.53 or 9d 32" is that the frog angle is not calculated as a right triangle.   There's no assumption that a frog is on a right or left handed turnout, but the same as if for a wye.  Makes less of a difference for smaller angles

frog angle = 2 * atan (0.5 / frog-number)

frog angles based on right-angle and isosceles triangles

     4    14.04 d   14d  2"    14.25 d  14d 15"
     5    11.31 d   11d 19"    11.42 d  11d 25"
     6     9.46 d    9d 28"     9.53 d   9d 32"
     7     8.13 d    8d  8"     8.17 d   8d 10"
     8     7.13 d    7d  8"     7.15 d   7d  9"
     9     6.34 d    6d 20"     6.36 d   6d 22"
    10     5.71 d    5d 43"     5.72 d   5d 43"
    20     2.86 d    2d 52"     2.86 d   2d 52"

From  Railway Track and Maintenance by RR Russell Tratman

Frog Number  Frog Angle

#5   11 deg  25 min

#6     9 deg  32 min

#8     7 deg  10 min

#10   5 deg  44 min

#20   2 deg  52 min 

Chart in book is in 1 deg increments from 5 to 20

Tratman lists three ways of measuring frog number .  #1 is "measure the distance, in inches, between between the points where the width over gauge lines is 2 in and 3 in, this distance giving the frog number."

In drawing posted by 7j43k  - where A is 2 inches and B is 3 inches, C is the Frog Number. 

9.46 degrees is 9 deg 27.6 min.

For a #6 frog:

If the frog angle is based on measuring back to the frog point from the midpoint of the line that forms the "1 unit" location, one gets 9 deg 32 min.*  See: 

http://www.pcrnmra.org/pcr/clinics/Kolm-TurnoutsWhatYouNeedtoKnow-PCR2008-handout.pdf

If the frog angle is based on measuring back along either rail to the frog point at the "1 unit" location, one gets 9 deg 34 min.

While pokin' around, I found this neat item on trackwork:

http://www.engr.uky.edu/~jrose/RailwayIntro/Modules/Module%206%20Railway%20Alignment%20Design%20and%20Geometry%20REES%202010.pdf

Ed

* Calculations deriving 9 deg 32 min for #6 switch:

tan x = .5/6

x = 4 deg 46 min

frog angle = 2x = 2 (4 deg 46 min) = 9 deg 32 min

 Doesn't seem like anyone mentioned, but the angle oof the frog is Arctan(1/frog number). So a #6 angle is arctan(1/6) or 9.46 degrees, and a #4 is arctan(1/4) or 14 degrees. All derived from the definition of the various Trigonometry functions and the basic fact that the frog number indicates how far along (adjacent side) you go to get 1 unit (the opposite side) apart. Since Tangent of the angle is opposite over adjacent (in the case of a #6, 1/6), then the angle by definition is the inverse tangent (arctan) of opposite over adjacent. Those that had Trig may remember SOHCAHTOA - Sine = opposite/hypotenuse, Cosine = adjacent/hypotenuse, and Tangent = opposite/adjacent.

                             --Randy

                   --Randy

More neat info!

Thanks, Greg

Ed

after hand laying turnouts, i looked at Variations in turnout dimensions.   The frog number describes the angle at the frog, not a distance.

the following diagram illustrates how NMRA turnout dimensions appear inconsistent depending on frog number.   The red closure rail is drawn with the proper prototype radius (see Catskill below) indicating where the frog should be located.   Most seem short (see bottom plots).

The Catskill Archive describes how prototype turnout dimensions are calculated (show below).

The radius (leftmost number) between the points and frogs can vary leading to various length (middle number) turnouts that are all the same frog number.  Blue section of closure rail is curved and red section is straight.

The key dimensions describe the distance between the points and frog.  That distance, the length of the diverging rails and those preceding the points may vary between manufactures and all be the same frog number.

Robert,

Consternation frequently leads to knowledge, so I will be thanking you.

I do not work in N.  I had no idea how "free form" some N scale trackage was.  Now I do.  My assumption that HO track switches are (close to/trying to be/are) NMRA correct will not be automatic, anymore.

And I especially appreciate your finding the NMRA document.  I expect to be hand building some switches in the future, and I'll take all the help I can get.

Ed

Sorry for causing so much consternation.

At least I've found something regarding my initial question. It seems somebody has investigated model dimensions vs prototypical dimensions:

NMRA Geometric Design

As for the other, I'll go with the dull Peco nomenclature.

Robert

7j43k

So then I would call them #6S, #6L, #7

One could name them Larry, Moe, and Curly -- but it wouldn't change what the manufacturer (and every other modeler) calls them. I don't see any good reason to add confusion, personally.

I checked my measurements and found I was wrong on the small one.

Corrected:

small--#5.7

medium--#5.65

large--#6.6

So then I would call them #6S, #6L, #7

Apolgies for the error.

Ed 

7j43k

So, no, they don't use the same #6 frog on all three.

I have the physical Code 55 turnouts myself, and they all seem to be the same frog. It would be strange to engineer products with such tiny differences in frog numbers, it seems to me.

ROBERT PETRICK

Hey Ed-

Yes, I am doing it wrong. I am measuring the switch lead and not that sharp pointy thing on the left. The lead is an important dimension in the geometry of a turnout. My contention is that Peco uses #6 frogs for all their turnouts. And as cuyama and others have pointed out, what happens downstream on the diverging route varies from manufacturer to manufacturer. My initial question was whether anyone has studied these discrepancies. My secondary question is what should I call my things. Calling them a number-seven-and-a-quarter-turnout-with-a-mismatched-ragged-number-six-frog is a bit cumbersome. And calling them a large-radius turnout is a bit dull.

But thanks for your imput.

Robert 

 

Robert,

Glad to be of service.

I am glad that you have fleshed out your concerns.  They haven't been clear up to now.

To your first question:  Someone first has to CLAIM or ESTABLISH discrepancies before they can be investigated.  I don't recall any such, but I/we might have missed them.  Nor do I (we?) recall any investigations.  So it looks like you are the first one to do so.  Therefore the answer would be, up to now: No.  But see below.

I downloaded from here:

http://www.peco-uk.com/page.asp?id=pointplans

photographs of N gage code 55 Electrofrog turnouts.  I measured the frog sizes:

small--#5.1

medium--#5.65

large--#6.6

So, no, they don't use the same #6 frog on all three.

My first thought on what to call them would be #5, #5 1/2, #6 1/2.  If that's too cumbersome, you could go with #5, #6, and #7.

Problem solved, I think.

Ed

cuyama

 

 

carl425

call them "Peco large-radius turnout"  and "Peco medium-radius turnout".

 

 

+1

 

That's what PECO calls them   http://www.peco-uk.com/

carl425

call them "Peco large-radius turnout"  and "Peco medium-radius turnout".

+1

7j43k

You are doing it wrong.

In simple words:  for the above, measure the width and the length of the outside dimensions of that sharp pointy thing on the left and divide.

Ed

Hey Ed-

Yes, I am doing it wrong. I am measuring the switch lead and not that sharp pointy thing on the left. The lead is an important dimension in the geometry of a turnout. My contention is that Peco uses #6 frogs for all their turnouts. And as cuyama and others have pointed out, what happens downstream on the diverging route varies from manufacturer to manufacturer. My initial question was whether anyone has studied these discrepancies. My secondary question is what should I call my things. Calling them a number-seven-and-a-quarter-turnout-with-a-mismatched-ragged-number-six-frog is a bit cumbersome. And calling them a large-radius turnout is a bit dull.

But thanks for your imput.

Robert 

ROBERT PETRICK

Can we look at this from another angle (as it were)?

I just got a shipment from MBKlein (another thread) and included were some PECO N Scale Code 55 Streamline stuff. I'm interested in two things in particular: one is labeled "large-radius turnout" and the other "medium-radius turnout". I took the things out of the plastic wrapper and measured each from apparent point of switch to apparent point of frog. I used a Starrett machinist rule and a (fairly-well) calibrated 60-year-old eyeball. I got 4.61" for the first and 3.65" for the second. Based on these measurements alone, what should I call these things?

 

 

You are doing it wrong.

Below is a picture of a Peco switch:

You can see the frog over on the left.  Measure it in the way I described earlier.  That will reveal the frog number.

In simple words:  for the above, measure the width and the length of the outside dimensions of that sharp pointy thing on the left and divide.

Ed

ROBERT PETRICK

Based on these measurements alone, what should I call these things?

Peco chose to disregard prototype practice and do their own thing (not that there's anything wrong with that).  There is therefore no name for them using prototype vocabulary.  You should call them "Peco large-radius turnout"  and "Peco medium-radius turnout".

Can we look at this from another angle (as it were)?

I just got a shipment from MBKlein (another thread) and included were some PECO N Scale Code 55 Streamline stuff. I'm interested in two things in particular: one is labeled "large-radius turnout" and the other "medium-radius turnout". I took the things out of the plastic wrapper and measured each from apparent point of switch to apparent point of frog. I used a Starrett machinist rule and a (fairly-well) calibrated 60-year-old eyeball. I got 4.61" for the first and 3.65" for the second. Based on these measurements alone, what should I call these things?

Thanks.

Robert

EDIT  In the meanwhile, I'm gonna download and read the link Byron provided. It is a zip file, and I could not read it yesterday on my cell phone.

If we're going to be nitpicky, there are regular turnouts, which have a straight diverging track after the frog, and curved turnouts, that have curved stock and diverging tracks.

The idea that a turnout's diverging track is curved comes in part from two things. One, a few model turnouts have a straight through stock track, but a curved diverging track. Two, the talk of effective radius, which is good to know, but doesn't necessarily mean there is a curved diverging track. Plus the points leading into the frog are curved, but what's past the frog usually isn't with a standard turnout.

ROBERT PETRICK

Okay, good. So, somebody somewhere has checked various manufacturers' offerings against NMRA (and AREA) specs for accuracy. Glad to hear that.

That's not what I posted -- I said that the frog numbers are generally accurate. The overall dimensions vary greatly from supplier to supplier, as I said. And NMRA and AREA specs differ from each other.

ROBERT PETRICK

so I'm calling my medium- and large-radius turnouts #6 and #8 respectively

Personally, I wouldn't, since it's not accurate. But I'm not building your layout. 

ROBERT PETRICK

I'm okay with designating their turnouts using the small-, medium-, and large- scheme, but that just doesn't sound very railroady, so I'm calling my medium- and large-radius turnouts #6 and #8 respectively. Mainly because that's what they appear to be as trains pass through them.

 

 

We've discussed how to be railroady.  

That doesn't give you license to call them #6 or #8, unless they are.

It is a very simple concept.

Ed

cuyama

I have not seen that, but it might be true for some obscure supplier. The frog numbers are typically accurate -- with the notable exception of the Atlas HO and N scale (Code 80) "#4", which is actually a #4½ (and thus, not quite as sharp). What happens on the diverging leg past the frog can vary from manufacturer to manufacturer.

 

Yes, this is what I was referring to. The majority of my direct experience is with N Scale, and I have used PECO Code 55 Streamline track and turnouts for well over 15 years. I'm okay with designating their turnouts using the small-, medium-, and large- scheme, but that just doesn't sound very railroady, so I'm calling my medium- and large-radius turnouts #6 and #8 respectively. Mainly because that's what they appear to be as trains pass through them.

I'm nit-picky about a lot of things but the slightly non-prototypical appearance of my PECO trackage and turnouts is not one of them. That stuff is well-made and very reliable. And by the way . . . PECO kinda plays a cover card in their advertising by calling their Code 55 flextrack visible Code 55. It appears to be about Code 75 rails with a double flange arrangement along the bottom.

Robert

peahrens

 

 

7j43k

Here is a drawing of a frog:

 

 

Here's another drawing of a frog.  (Steve started it.)

https://s-media-cache-ak0.pinimg.com/originals/b8/ea/56/b8ea562f15be0f3298fe733e2dbf539e.gif

 

 

Well, yeah.  But is it a #4 or a #20.  THAT'S the problem we're thrashing out here.

Ed

7j43k

Here is a drawing of a frog:

Here's another drawing of a frog.  (Steve started it.)

https://s-media-cache-ak0.pinimg.com/originals/b8/ea/56/b8ea562f15be0f3298fe733e2dbf539e.gif

Here is a drawing of a frog:

It is what defines the "number" of a track switch.  The "number" is derived from choosing an arbitrary distance between the "point rails" (which are NOT related to the movable points of the track switch) over to the right and finding how many times that divides into the distance between either point chosen and the "theoretical point of the frog" (back to the left).  As we all know, they can be blunt (#4) or sharp (#20).

Railroads have a huge tendency to continue the frog point rails in a long straight line as far as they can.  The longer they are, the less likely there will be a derailment or other irritations.

In the real world, people have been known to choose a point on the diverging frog rails that is the length of their shoe, and walk towards the frog point.  The number of "shoes" will indicate the frog number.  Of course, that is considered by many to be unsafe, but it does give you a visual of the ratio.

As mentioned above, you can measure a model one.  Choosing a Walthers Code 83 #10 switch, I chose an arbitrary point "a ways" out from the frog (being sure by sighting down the rails that the two appropriate rails remained straight after the frog).  I measured the width between THE RUNNING SIDES of the two rails and got .338".  From that point I measured back to the theoretical point of the frog (the real one on this sample being kinda blunt) and got 3.39".  Dividing, we get a frog of #10.03.

Frogs are almost always "straight", rather than "curved".  Both in the model and the real world.

Ed

ROBERT PETRICK

it seems that some store-bought turnouts use the same #4 frog but increase the radius of the diverging track and call the new thing a #6. Or a #6 a #8. Or whatever.

I have not seen that, but it might be true for some obscure supplier. The frog numbers are typically accurate -- with the notable exception of the Atlas HO and N scale (Code 80) "#4", which is actually a #4½ (and thus, not quite as sharp). What happens on the diverging leg past the frog can vary from manufacturer to manufacturer.

[The Atlas N Code 55 frogs are accurate as listed.]

ROBERT PETRICK

Peco has eschewed numbering altogether and calls their turnouts small, medium, or large. Perfectly reasonable and descriptive, but some folks might want exactitude.

This is true for PECO N Scale and for PECO HO Code 75 and Code 100, but the newer PECO HO Code 83 is accurately defined by frog number. PECO N scale Code 55 uses a #6 frog for all the turnouts, but the curved diverging leg has different radii for Small Medium, and Large, for example. PECO HO Code 75 and 100 typically have a #4½ frog, again with different diverging radii past the frog. So they are “exact”, but the curved diverging leg is the determining factor.

Barry B

What is the difference between a #4 turnout and a #5 turnout?

The first is that, generally speaking, the larger the frog number, the longer is the turnout itself. So smaller frog numbers are often chosen in tighter spaces. The exact length varies from supplier to supplier -- and pre-fab turnouts can often be trimmed a bit.

The second (and more important) is that the lower the frog number, the sharper the effective curve through the turnout. That means that longer cars and engines will be less likely to derail running through a #5 than through a #4.

For this reason, it's a good idea to match the turnout frog to the minimum radius elsewhere on the layout. To take an extreme, there's no point in using #8 turnouts with 18" radius curves in HO -- the curves will restrict the equipment that can be run.

As a general rule of thumb for HO, the tightest point through various frogs is:
"True" #4 is roughly equivalent to 14"-15" radius
Atlas "#4" (actually #4½) roughly equivalent to 18"-19" radius
#5 roughly equivalent to 24"-25" radius

These calculations are from a series of datasheets published by the National Model Railroad Association. An out-of-date link was given above, the newer version of the website is a downloadable zip archive of .pdf files found at this link:

http://www.nmra.org/sites/default/files/standards/sandrp/pdf/rp-12s_pdf_files_12.1_to_12.54.zip

[This is kind of cumbersome and I wish the NMRA had published these as individual web pages as before. The critical dimension is (11), which is the tightest curve through the frog.]

To the original poster, more information about your scale, the type of equipment you'd like to run, etc. will help others help you. Good luck with your layout.

Byron