Sunday, June 24, 2018

GL1000 -- Steering Head Bearings

"I have not failed. I have merely found 10,000 ways that do not work." --Thomas Edison

Before wrapping up the GL1000 project for the "winter" (now that it's the middle of June), I needed to replace the steering head bearings. During my ride to Whittier for a cup of coffee (lol) last Father's Day, I noticed that the steering on the bike felt a little notchy. Since I don't know the service history of the bike -- in fact, I don't even know its total mileage -- I decided that I should probably replace the steering head bearings after the riding season ended, which was probably a wise decision. Waiting until the next riding season before starting...that, perhaps, was not quite so wise ;)

In theory, this should be a pretty simple task. It's a lot of steps, but each task is pretty straightforward. Nothing too difficult, right?

Well...yeah, that's the theory, but like they say, "In theory, theory and practice are the same. In practice, they aren't." First, I needed to make a tool to remove the steering stem nut. Honda, in it's infinite wisdom, decided to forsake a traditional six-sided nut on the steering stem for this weird, round thing with four grooves cut in it. There is a specialty tool available on-line for around $50, but I managed to find one elsewhere for $27...plus $48 shipping and handling, sigh. However, you can make a reasonable substitute from a suitably sized socket by cutting it with an angle grinder to fit inside the grooves on the nut. For the record, "suitably-sized" for a 1978 GL1000 happens to be a Kobalt 28mm socket from Lowes (but not the 26mm or 30mm sockets that I also tried).

With the steering stem nut removed, I tried to drop the lower triple tree out of the headstock, but found that I also had to remove the forks, then remove the "Honda" name plate from the lower triple tree so that I could disentangle the wiring to the headlights and instrument cluster from the lower triple tree. That added a few more steps, but nothing too terribly bad.

Once the forks were free, it was easy enough to remove the lower triple-tree and the upper bearings.

Next, taking some advice I had found on the Naked Goldwings Forum, I had bought a threaded rod, a large-area washer and two bolts to use as a drift to punch out the lower bearing race from the headstock. Unfortunately, the large-area washer was too large-area to fit inside the headstock, $@#%!!! Fine, the traditional DIY way to pop a bearing race out of a tube is to use a long flat-bladed screwdriver as a drift. I have plenty of such screwdrivers, so I tried that, but the lower bearing race is behind a lip that prevents a screwdriver from finding purchase on the top edge of the race.

No problem; while reading through yet another thread on-line about replacing bearings on vintage Goldwings, I found instructions to make a different DIY bearing race removal tool: take a 1 1/2 inch diameter piece of pipe, cut four slits vertically (lengthwise) in the pipe, so that the bottom can flare out slightly, then place it over a ball hitch and hit it with a hammer to flare it. I still couldn't get a purchase on the lower bearing race...

...but it worked like a champ on the upper race. Yay!!! Partial success!

After a lot more searching on-line, I hit upon the idea of making another tool out of a piece of angle iron, but that didn't work either. At this point, I was starting to think that perhaps I was in a little over my head, but while holding a hammer while trying to get the angle iron to grip on the lip of the race, it suddenly occurred to me to try using the claw on the hammer to slowly and carefully pry the race out of the head. To be clear, I wasn't sure this was a good idea -- in fact, I was pretty sure that it wasn't a good idea, but I was getting desperate. To my surprise and relief, the race popped free after just a few minutes of prying with the claw on the hammer.

The next task was removing the lower bearing from the steering stem itself. One suggestion I found on-line was to use a thin abrasive cutting disk on a Dremel to cut most of the way through the lower, inner race and then to use a chisel to split the race. I cut most of the way through the race, but couldn't get it to split. Another suggestion was to run a bead around the race with a welder, so I fired up my cheap MIG torch, but no -- yet another tip that didn't seem to work for me. As I racked my brain for some other way to work the race free, I kept finding my attention drawn to the chisel. Finally, on a lark, I used the chisel as a wedge between the race and the lower triple tree, which actually worked! With a little space between the race and the triple tree, I swapped the chisel for a pair of pry bars and was finally able to work the race free of the steering stem.

After all the difficulty removing the old bearings, I was not at all thrilled about the prospect of putting it all back together again, but it turned out that installing the new bearings was considerably easier than removing the old ones. I drove the new lower, inner bearings into place using another section of the same pipe that I used to make the wedge that I used to pop the upper, outer wedge out of the steering head -- no fancy tricks, just place the pipe over the race, and tap it into place with a hammer. The outer races were also easily tapped into place with a hammer, using the old race to help drive the lower race once it was completely inside the head (split the old race with an abrasive cutting wheel first, so it doesn't get stuck in the head, too). Then slip all of the pieces back together, and the steering head is done! Yes, that's actually a lot of hand-waving over what was actually about two hours work, but it really was pretty straightforward.

Once the steering head bearing replacement was done, there were just a few simple tasks left to wrap up: an oil change; finish seating the bead on the front tire (setting it outside in the sun for a couple of hours, then hitting it with 110 p.s.i. of air did the trick); remove the old non-resistor type spark plugs with new iridium, resistor-type spark plugs; install the proper 30A "dog bone" fuse in place of the bare wire that the previous owner used (!) and suddenly, after six months, the Goldwing was ready to ride again!

It wasn't a long ride, just out to dinner with my wife and a quick trip to the grocery store, but it was good to have the 'Wing back again.

Sunday, June 17, 2018

GL1000 -- Ignition (and other) Upgrades, Part 2

Has it really been five months since I ripped into the Goldwing?!?! I am nothing if not a procrastinator, I guess...Anyway, after a three month hiatus, I finally decided to wrap up the ignition upgrade and cooling system rebuild, since summer has now arrived in Alaska, and I really want to be riding my 'Wing again!

When I was researching the Dyna ignition upgrade, one of the common failure modes of the Dyna was to lose the 12VDC power to the ignition. Dyna recommends taking power from the accessory module under the left-hand shelter cover on '78 model year GL1000's. However, I have seen a short elsewhere in the electrical system take out the accessory power, since the tail light wiring is tied into the same fuse as the accessory power. Furthermore, I'm not too sure I want to power my ignition (where I want really good input voltage and current) from the same source that powers the tail lights, my heated jacket and whatever other electrical doodads I decide to add in the future. On the other hand, I don't really want to completely redesign the entire electrical system on the bike either, particularly now that riding season is in full swing. So, I decided to compromise: I wired up a 20A relay between the battery and the accessory block, triggered by the current that used to power the accessory outlet. If I get another short in the tail light wiring, I'll still be dead in the water, but I've at least got current directly from the battery to the ignition. It's not an ideal solution, but maybe I'll revisit the design next winter.

Once I had power to the ignition, I got started setting the timing. Dyna recommends connecting a test lead to the coil input, but Octane at Naked Goldwings posted a really, really good how-to (registration required, I believe), where he points out that you can simply tap into
these connectors right here to verify your points timing -- much easier than trying to access the coils directly! However, when I turned the key to the "on" position and rotated the engine two complete revolutions, I was unable to get my test light to light up. Okay...how about the other coil? Nada. Hmmm...what gives? The ignition has been sitting in my garage for a little over a year (just long enough for the warranty to expire, @#$%!!!), but I can't imagine that would cause it to fail. After troubleshooting for the better part of a day, I called it a night, and watched YouTube videos of a guy riding a modern Goldwing in Japan for a while, lol. When I woke up the next morning, I had an epiphany: "The ignition is grounded -- i.e., no voltage -- when the run switch is in the 'off' position. You never put it in the 'on' position!" Could that really be it? No...couldn't be. I had completely removed the ignition from the bike and bench tested it! I jumped out of bed, reinstalled the ignition in the bike, turned the key on, turned the run switch on, and was rewarded with a brightly lit test light -- well out of spec for the timing, but at least proving that the Dyna worked! Timing the ignition per Octane's instructions was tedious, but easy. Notice how many times he says, "...the marks on the flywheel should line up...probably don't...?" There's a reason for that, lol.

Once the timing was set, I reinstalled all of the various covers, placed split-loom tubing over the new power wires to the ignition and accessory box, and got started on the next item in my checklist: the air cut-off valve.

This device...actually, I'm not entirely sure what it does, but what I do know is that there are several little rubber o-rings and a slightly larger rubber diaphragm that eventually get brittle and crack, allowing air to leak into your intake system on the wrong side of your carburetors, leading to a lean condition, especially at idle or when using engine compression to slow down. If this happens, you'll hear a burble when you release the throttle -- something I've noticed on my bike. I had picked up a rebuild kit from Saber Cycle (Randakk sells one too, but I found it on Saber Cycle first). On GL1000's, it's really simple to remove: just forward of the air box, under the spark plug wires and next to the #1 carburetor is a small, round metal object with a rubber hose plumbed into it. Pull the hose free, then remove the two LOWER screws (the top two screws hold the cut-off valve together), and lift it up through the shelter.
Rebuilding is almost as easy: remove the top two screws, and carefully pull the cut-off valve open, paying attention to the orientation of the rubber diaphragm (the metal bump should be on the underside of the diaphragm). Use a pick to remove the o-rings, and use just a dab of grease to hold the new o-rings in place while you reassemble the valve. Piece of cake!

With the air cut-off valve rebuilt and back in place, it was time to button up the intake systems, so I replaced the airbox-to-carb gasket, and started to reinstall the airbox. Of course, nothing is ever as simple as you expect, right? Because the Dyna coils I installed are slightly larger than the OEM coils, the installation instructions say "you might have to" cut a short piece off of the intake snorkel on the airbox. I was hoping I could get away without surgery on the airbox, but no. With the airbox about 80 per cent in place, the intake snorkel was pressed up against the towers and upper spark plug wires, so I pulled the airbox free and modified the intake snorkel with my angle grinder. Truth to tell, had I known this was necessary, I probably would have looked for a different set of coils. I know that the GL1000 is pretty sensitive to changes to the intake system, and since my airbox is in pretty good shape, I'd rather not cut on it if I don't have to. Unfortunately, when I bought the coils, I didn't know that the airbox wouldn't fit, so now, given the choice of cutting the airbox or replacing a brand new, perfectly good set of coils, I opted to modify my airbox.<shrug>

Next, I had to figure out how to route the hoses for the crankcase breather. In between garage sessions, I had looked on-line for a diagram that showed which hose ran to the crankcase breather opening and which ran to the drain cup, but was not successful. I figured I could probably figure it out by looking at the lengths of the hoses, since the drain cup sits lower than the breather opening, but as it turns out, the solution was even simpler than that: the nozzles on my airbox are labeled "drain" and "engine," lol, making it extremely easy to determine which hose goes where!

With the airbox reinstalled and the crankcase breather reattached, the next project was swapping out the front wheel. When I bought the bike, the previous owner included a boat-load of spare parts: an extra set of wheels (front and rear), an extra pair of front brake discs, floor boards, a Vetter fairing, an extra rack of carburetors, and I don't even remember what else. Last summer, when I replaced the front tire, I found that the installed wheel was in rather poor condition, with the inside of the wheel gouged up pretty badly by tire irons. I'm not great at replacing tube-type tires, but out of four previous tires (front and rear each on my XS750 cafe racer and my wife's CB750 Hondamatic), I had only pinched one tube.

I punctured THREE brand new tubes while replacing the front tire on the 'Wing, and NONE while replacing the rear tire.

I'm not saying that I can't be as much of a ham-fisted monkey with a tire iron as anyone else, but I find it really hard to believe that I got so lucky with two other bikes (and half of this one) and so UNlucky with the front tire on this bike. Since I also seem to have a slow leak with the tube currently installed on the front tire, I decided to take the downtime on the GL1000 to replace the bearings on the spare front wheel, move the brake discs off the existing front wheel and onto the spare front wheel, install a new rim strip and a new heavy-duty tube on the spare front wheel, move the existing tire to the spare front wheel, and finally reinstall the whole assembly on the bike.

First order of business: removing the old dust seals from the spare wheel, which proved to be far more difficult than you would expect. My seal pullers simply tore the seals, even after heating them with a heat gun. Eventually, I pried into the outside (:eek:) edge of the seal with a tiny, flat-blade screwdriver, and popped the seals off. Gotta love 40 year old parts, sigh. I also mangled the old speedometer gear retainer and the bearing retainer on the other side of the wheel. Note to self: Honda makes a tool especially for removing the bearing retainer, or you can grind one out of a suitably-sized socket. A hammer and screwdriver does NOT make a suitable replacement for the proper tool. Fortunately, Bike Bandit had replacement parts for a not-terribly-unreasonable price...but it would have been cheaper to buy the proper tool. Amazon supplied a replacement set of bearings and dust seals from All-Balls, and a few minutes with a hammer and a large-diameter socket resulted in a firmly seated set of bearings in the wheel. Note to self, again: read the instructions in the Clymer manual before seating the bearings. Only ONE bearing should be firmly seated; the other should LOOSELY rest against spacer between the bearings. You'll know you've seated the bearings too tightly when they won't turn properly. See? I can be just as ham-fisted as the best of them, sigh. I think I managed to solve that problem without ruining the bearing in the process. At least, I hope so, anyway.

Once I had the new wheel ready to go, it was time to pull the old wheel and move the brake disks and tire to the new wheel. Once I started removing components from the old wheel, I got a reminder that this bike is almost -- but not quite -- as old as I am. The five bolts that hold the brake disks to the wheel were covered in white and orange corrosion (aluminum oxide from the wheel, and plain rust from the bolts, I presume), and the axle was coated in a thick, reddish-orange paste of congealed grease and rust. A combination of engine degreaser, a brass cleaning brush and 600-grit emery paper did a passable job of cleaning up the axle, and a wire brush on my drill greatly improved the condition of the bolts for the brake disks.
After getting the wheel and bolts cleaned up, I reinstalled the brake disks on the wheel, ready to be installed after replacing the steering head bearings...but that will the next post ;)