Skip to main content

Coupling Rods



The spacing of the coupling rod centres is critical to the free running of the loco. I measure each side separately and comparing it with the drawing. Any inaccuracies in making up the axle-boxes or in setting the crank-pins will show up here.

I started by marking out the centres and outline on the rod blank, then drilled the centres, starting with a small centre drill, then drilling out at (say) 2BA clearance at one end, and 2BA tapping at the other.

The rods tapered from 3/8 to 1/4 in. - i.e a taper of 1/16 in. on each side.
So I marked out the centre line on the support bar, and another, offset by 1/16 in. I drilled and tapped a fixing for one end of the bar on the centre line, and attached the rod blank. Then I lined up the other centre on the 1/16 in offset line, clamped and drilled through 2BA tapping. Now I removed the rod blank, and opened the 2BA tapping hole on the rod blank to 2BA clearance. Also I tapped 2BA threads in the support bar and bolted the two together.

I clamped the support bar in the milling vice, parallel with the main axis of the milling table. I then cut away one side of the taper, turned the blank over (i.e. upside down) and cut away the second side.

I then rotated the entire assembly of support bar and blank through 90 degrees in the milling vise, and milled the back to profile. If, as in my case, there was a slight taper on the back of the rod, I set this up by making a spacer washer equal to the taper, and placed it under the appropriate 2BA fixing bolt.

I then opened up the bearing holes to their running diameters - in my case, 1/4 and 3/8 in.



In the case of the trailing coupling rod, I decieded that the most accurate way to measure it was to mark it out directly from the job. I made up a piece of rod as a scribe - the photo says all!
Once all the coupling rods had been made up to this point, I was able to try them on the chassis, and check that they ran freely. The chances are that they will stick at some point and it may be necessary to 'modify some of the hole positions - the drawings show the driving axle bearings as 'reamed', whilst the driven bearings as shown as 'drilled' indicating that some clearance is to be allowed. Once I was satisfied with the hole positions, I enlarged the holes to accept the bushes, which were pressed in, and finally re-reamed. I actually reamed them all, and, had it been necessary, would have opened up the driven bearings with an expanding reamer.

To create the radius around the big-end eye - I cut away as much surplus as possible. With the big-end located on a 3/8 round bar in a machine vice. I clamped this to the table of my bench drill, and presented this to a grinding wheel in the drilling chuck. I held the other end of the coupling rod by hand, and slowly rotated it against the grinding wheel. The radius was soon established.

I've seen a similar arrangement suggested using a milling cutter in a vertical mill. I did try it once, but never again. I thought it dangerous and would strongly advise against it.
Labels:

Comments

kunal said…
Hi there. Nice blog. You have shared useful information. Keep up the good work! This blog is really interesting and gives good details. gear coupling, flexible couplings manufacturers India.
March 12, 2012 at 3:15 AM
kunal said…
Hi there. Nice blog. You have shared useful information. Keep up the good work! This blog is really interesting and gives good details. flexible couplings manufacturers India, gear coupling suppliers in Delhi.
April 9, 2012 at 3:17 AM
rob said…
Pity you photos are not focussed; makes it difficult to see the work.
Otherwise useful information
July 3, 2012 at 12:56 PM
Post a Comment

Popular posts from this blog

Wheels

What I started with was a set of frames with hornblocks fitted, and wheels turned. So I'm afraid I've no construction details for these. Except for quartering the wheels. You can do this either with a jig,or in the lathe. I've used both methods - a jig works well. Most books and drawings show jigs which are specific to one model, which is not brilliant. Since then, I have seen a general one detailed, which is a far beter idea. I've also quartered wheels in the lathe, which is what I chose to do this time. Two sets of wheels were already assembled and quartered, but, when I checked them, both were different ! The object is to set the two wheels on an axle at 90 Deg to each other -usually, the right leads on British locos. Having said that, the really critical thing about quatering is not the exact angle, but is that all the wheelsets on the loco must be set at EXACTLY the same angle. This is because the wheel relationships are locked by the coupling rods, and any diffe
Post a Comment
Read more

Tender Body

The original drawings showed what I think is the Hawksworth tender - I've previously made one in 5 in gauge, and thought the Collett tender would make an interesting change. It has a couple of major challenges - the top of the sides are flared, and also the rear corners of the tand are very rounded, so a tricky compound curve is created where they meet. I took the basic dimentions from the drawings, and scaled the Collet specifics from a couple of photographs. The fact that the major lines of the tender matched up with the profile of the cab gave me some useful reference points. Then there's a raised extension which fits on top. I left a tab which I curved to match the lower part of the tender, and riveted and soldered the two together. The other tricky bit was the rivets -there are several hunders of them, and they're very prominent. My solution was to make the tender tank out of thinner brass than usual -about 22 gauge. (Another reason for this was that I had a couple
2 comments
Read more