While machining the pistons last August (post #108), I made two sets: a high and a low compression pair. I've decided to use the low compression pistons since they'll present less of a load to the starter motor. Although it wasn't necessary, I machined 'eyebrows' into them for a bit more valve clearance. Even at their mild 5.3 compression ratio, the edges of the engine's huge valves come uncomfortably close to the hemi-topped pistons. After installing rings on them it was time to begin final assembly.
While re-installing the cylinders, I decided to replace the small pattern 10-32 nuts that I had been using to mount the cylinders to the crankcase and the heads to the cylinders. It was a nit-pick, but the nuts I was using never looked at home on the engine. I spent a day machining a couple sets of flange nuts that are not only more appropriate but provide a few more threads. After bead-blasting, they were painted black with baked-on Gun Kote so they'd blend in with the blued cylinders.
Another last minute but much more significant change was to replace the bolts in the rocker boxes with studs. In the original design, these bolts not only secure the covers to the rocker boxes, but they're also the shafts for the rocker assemblies. I finally realized that because the heads of the bolts are on the outsides of the rocker box covers, a lot of disassembly was going to be required to merely verify the rocker boxes are properly receiving and draining oil. All four of the 4-part rocker arm assemblies were going to have to be pulled in order to remove the covers, and this means the pushrod assemblies would have to be removed as well.
Both ends of the studs were drilled/tapped for 5-40 setscrews that were installed with permanent thread-locker to provide wrench-able hex sockets. The studs not only allow the covers to be removed without disturbing the rocker assemblies, but they also simplify installation of the pushrods and covers.
I wanted to duplicate the signature acorn nuts I've seen on the rocker boxes of the full-size engines. I was about to machine my own when I located some already polished stainless acorns of the correct size in my collection of scrap fasteners. The only problem with them was that they were threaded 1/4-20 instead of 10-32. Since there was no room for a threaded adapter, I bored the nuts out for plugs that were pressed, Loctite'd, and pinned into place. After threading the plugs, I made a set of teflon gaskets to seal them to the covers.
Another loose end involved sealing the four valve box covers. These covers have extremely narrow mounting flanges with lots of mounting holes and aren't well suited to a conventional gasket. I didn't want to use a messy sealer, so instead I used this vinyl sheeting that I found in a local craft store:
https://www.amazon.com/Oracal-Glossy-Permanent-Vinyl-Inch/dp/B01N42YR3P/ref=sr_1_6?crid=2HA1C5QA6S92E&keywords=oracal+651+vinyl&qid=1558133549&s=gateway&sprefix=oracal+651+vinyl,aps,183&sr=8-6
It's 2.5 mils thick, adhesive-backed, and intended for making rub-on stencils. Its adhesive probably won't stand up to fuel or to significant heat. But, in this particular application as a gasket completely sandwiched between two machined surfaces, it should be satisfactory. After cleaning the covers with alcohol, they were set down onto the adhesive side of the sheet so the material could be trimmed from around their peripheries using an Xacto knife. Working from the non-adhesive side, the holes were cut remarkably clean using a chucking reamer held in a pin vise.
The gearbox assembly began with the installation of the oil pump and camshaft. The pushrod/cover assemblies were then installed and the valve lash set. I used the doweled plexiglass fixture plate constructed earlier for temporary outer bearing support since the valve train exerts a significant downward force on the camshaft. When it came time to install the starter chain drive assembly, the fixture plate had to be carefully removed to avoid extracting the cam.
With the starting system in place, the gearbox cover could be installed. With the cover engaged on the gearbox dowels, a piece of 3/32" steel welding rod inserted horizontally behind the cover was used to push the outer end of the camshaft upward so the cover could be slid into place. To remove the cover, a thin spatula can be used to prevent the camshaft from being pulled out of place. If this happens, the lifters, the pushrods, and their covers will have to be removed in order to re-install the cam. I practiced this maneuver with a paint scraper to make sure it was feasible.
With the gearbox cover bolted in place, a test could finally be made of the fully loaded starter inside the engine. Spark plugs were temporarily installed and the flywheel manually turned over a few times. Plenty of compression was evident - much more than in my Howell V-twin. Neither of my shop-made model engine compression gages can fit inside the plug recess in these heads, and so I couldn't make an actual compression measurement. The good news was that the starter had no difficulty in cranking the engine. The starter motor that's currently in the engine is the 165 rpm gear motor (post #148) which spins the engine at 200 rpm.
The distributor was then installed and the timing set to about 15 degrees BTDC using the timing light feature that I designed into the ignition circuitry (post #167). Looking down on top of the distributor, the rotor spins clockwise which is opposite to the direction of the distributor in the original drawings.
Before installing the carburetor, I added 30 ml of oil to the sump and then spent the next few days chasing oil leaks. The first one, which I should have anticipated, occurred between the bottoms of the valve boxes and the heads. This issue concerned only the two outside valve boxes since they're mounted at steep angles. The oil that collects inside them can't drain quickly enough through the tubes intended to return the oil to the crankcase, and so some oil seeps out between the bottom of the valve box and the top of the head.
The leak was easily solved without disassembling everything that had just been assembled. After dropper'ing acetone into the spaces between the valve boxes and heads to flush out all traces of oil, I dropper'd in a small quantity of Loctite 290. This product is a wicking thread-locker that will easily and permanently seal gaps up to .005" after an overnight cure. I should have removed the drain tubes before applying it because I managed to also seal one of them up and eventually had to fabricate a replacement. - Terry
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