Something to think about

Holy Heisenberg!

Yes, but not a sine; rather, a cycloid.

The side rods and any part of the wheel except the axle actually are always moving forward but in a sine wave pattern. They are travelling fastest at the top and bottom of their travels and slowest at far left and far right of the axle. Clousers diagram doesn't take into account the fact the entire assembly is moving forward faster then the siderods back and forth motion which cause them to move slightly faster then the locomotive on their forward stroke and slighty slightly slower on their reverse.
If you take a series of still photos of a locomotive moving and then plot the axle and the siderod post from the photos on a graph it becomes readily apparent, at least it did when we tackled this problem in physics class.

I stared at Clousers animation until, now I have a headache...Tim

And here I thought toy trains were just toy trains ........[(-D]

QUOTE: Originally posted by FJ and G Did you know that when you walk and chew gum at the same time, there's a slight pause as your teeth mash down on the gum and as you land on each foot?

And, all of my research shows, despite there being no mechanical connection between the two components involved, the pauses are coordinated.

I'd like to thank the Academy and Wayne for this award. Does this mean that it can no longer be said that I don't know whether I'm coming or going?

And the winners are...

MEMBER GRADE

lionelsoni A+, for Absolutely correct and + for adding the part about the flanges.

Clouser A, for Absolutely fantastic animated gif. Thank you for that.

Awww, ....#@$& it!

I'll tell you what, not only do I have a Migrane now but I can't stop my head from rotating from woatching my M1a. THANKS----THANKS ALOT ODD?!?


Jim D.
a.k.a.SOCKO

Dave You probably don't see much of that in DC!!!!! Walking AND chewing gum!

underworld

[:D][:D][:D][:D][:D]

Did you know that when you walk and chew gum at the same time, there's a slight pause as your teeth mash down on the gum and as you land on each foot?

Does this make any more sense for a car than for a locomotive's siderod? If you are driving an automobile smoothly down the road you will have to agree that at some point you might be behind another car and at other times in front of that other car; so it stands to reason that in order to get behind the other car you must move slower than the other car on the horizontal plane of the road, thus slowing down to a stop so that you can accelerate again to pass the other car.

If you had been a student in Mechanical Engineering, you would have studied this concept in your mechanics of machinery course. Specifically, they call it Linkwork. The function of a link mechanism is to produce rotating, oscillating, or reciprocating motion from the rotation of a crank or reverse. (There is much much more, but I don't want to type it all out.)

A good source for those interested in locomotive steam engines is:

Mechanics of Machinery
by C.W. Ham and E.J. Crane
McGraw-Hill
1938

I can't believe I know anything about this stuff. Obviously I am living too anal of a life for my own good.

Vitabile

QUOTE: Someone has probably done this work before

Yep, Copernicus, about five hundred years ago. Got his protege excommunicated for heresy.

The wheel, as a whole, moves forward at the speed of the train. The bottom rim of the wheel has zero velocity in relation to the track, otherwise it would be slipping. Therefore, the top rim of the wheel must be traveling at twice the speed of the train in relation to the track to maintain the average velocity of the entire wheel. In order for the drive rod to move backward in relation to the track, it would have to be attached to the wheel outside the rim resting on the rail that has zero velocity. Although not impossible, I have never seen such a driver wheel set up, ergo, the drive rod never goes backward in relation to the track.

[8D]

Clouser...now you're really gonna get the Physics boys goin' about spatial relativity...this could get interesting!

Odd-d,

the General is my favorite train movie and I remember that scene. Buster was really on cloud nine when he was doing that stunt.

I'd be interested to know what the valve gear is doing. I think that stops too.

Those valve gears, siderods, main rods, etc, make steam train watching so exciting. That's why I never really cared for those streamlined steam locomotives with their sheathing.

Why hide it? Flaunt it if you've got it.

Odd-d is right they are moving forward and backward:

The side rod is always moving forward, sometimes slower, sometimes faster.

QUOTE: Originally posted by Odd-d Here is the point that I think will illustrate my observation.......if you watch a steam engine run smoothly down the track you will have to agree that at some point the siderod crankpin is behind the axle, and at other times it is in front of the axle so it stands to reason that in order to get behind the axle it must move slower than the axle on the horizontal plane of the track thus slowing down to a stop so it can accelerate again to pass behind the axle to the point above the axle where it has to decelerate again. AW NUTS!! Now I'm getting a headache. I guess I'll take a nap and let you younger guys figure it out. Odd-d

Well, yeah, but your assumption that the side rod stops when it gets directly behind the axle isn't necessarily correct. The speed of a point on the side rod depends upon subtracting the part of that point's velocity that is parallel to the train's direction of movement from the engine's speed in the same directrion. If the engine is moving faster than the side rod, it will never travel backwards or stop, relative to a viewer standing on the ground.

Relative to the train itself, the side rod is just going around in circles. It all depends on where you stand when you look.

YOu really need to draw some diagrams & break out the trig to analyze this.

Tony

I have a BS in physics, which I got 23 years ago.

This is problem which is going to take some analysis & I don't have time for it now. Someone has probably done this work before & it may be on the Internet. I'd do a search.

In any event, selector is right in that the side rods just go around & around, but so what? I don't think he's right that the motion with respect to the ground is irrelevant -- as Einstein said, everything's relative. Said another way, one point of reference is as valid as any other.

To an observer on the ground, it's possible that the side rod never actually goes backward, if it's speed along the track is faster than its tangential speed around the axle. This is the same thing that happens if you throw a snow ball out the back end of a vehicle that's going faster than you can throw the snow ball. To you, it looks like the snow ball is moving backward, but to someone on the ground, it's just going forward at a speed slower than the car.

The forces felt by the side rod are primarly the pushing & pulling forces from the piston. There's also the centripdal forces from going around with the wheel, but the vector associated with centripidal force points along the axis of rotation.

I really don't want to think about this one any more, it's giving me a headache.

Tony

Here is the point that I think will illustrate my observation.......if you watch a steam engine run smoothly down the track you will have to agree that at some point the siderod crankpin is behind the axle, and at other times it is in front of the axle so it stands to reason that in order to get behind the axle it must move slower than the axle on the horizontal plane of the track thus slowing down to a stop so it can accelerate again to pass behind the axle to the point above the axle where it has to decelerate again. AW NUTS!! Now I'm getting a headache. I guess I'll take a nap and let you younger guys figure it out. Odd-d

And a Cyclops is a monster with one eye![:D]

Now that we have straight we can move on! [:)]

Crandell, the path taken by a point inside the rim, like the cranks and siderod, is called a "curtate cycloid". There is also a name for points outside the rim, "prolate cycloid". This is the path taken by a point on the flange, which is the part of the locomotive I referred to above that not only moves forward more than twice as fast as the locomotive generally but also briefly moves backward. In fact, some part of every flange of every wheel of a moving train is always moving backward!

I hope this dosn't turn into one of those "calculating drawbar pull" threads. [:D]

Thanks to Odd-d, I now have a headache. [:(]

If anyone has a 4-4-0 at home, I got a bunch of frequent flyer miles.....I'd be willing to use some to try out the Buster Keaton stunt![:p]

underworld

[:D][:D][:D][:D][:D]

Ben is pretty good with that stuff, I care not to know

Is there a mathamatician, or physicist, in the house? (Pardon my spelling)