Based on what I have read, not scientific evidence that anyone had proven to me, the rings are designed to move radially in their grooves and work their way around the pistons over time. That movement helps keep the grooves clean and the rings free. By running the RPMs up and then closing the throttle abruptly you create the right conditions to encourage the rings to spin. That prevents them from sitting in one place where a little gunk can build up.
Great post, and glad to see you took pictures to document everything....which I didn't. These engines are impressive, and I'm a big believer in FJR longevity after getting intimate with the inner workings of her heart. I love bikes that you can put big miles on, I also have a Triumph Tiger that's got almost 95K miles on it.
During a leakdown test you can listen very carefully to what is leaking. If exhaust valves, sound will eminate from the exhaust ports, intake valves, intake ports. If no sound is coming from either of these, then it is rings.
The small bit of info I got from the shop said they heard air leaking from the oil filler port, meaning leakage past the rings. That's why I tried the oil in the cylinder trick and now I wish I had used some Ring Free or something else....just for the heck of it to see if it could have got the engine running better. I also wish I had done a compression check or leakdown test myself, but I had already jumped on the cheap engine deal so I sort of sealed my fate.
Yes, the oil filler port, I should have listed that as option 3. Good that they listened and gave you the info on the rings being the possibility.
Yep. Might as well ride a 650 if you don't use the muscle of the FJR.
From what I remember reading, the FJR was originally designed to run wide open all day on the Autobahn. It wasn't originally destined for the US as I recall and only considered when we kicked up a ruckus. One look at the top down cooling system design shows intent on keeping the combustion chamber cool under maximum throttle. I wish all engines had a design like that.
Erm, no. There's a pressure relief valve, spec'd to 480-560 kPa (69.6-81.2 psi), so after this is reached, no further increase pressure with rising rpm.
I'm curious, what do you mean by "top down cooling system"?
The minimum oil pressure (at idle) is only 4.4 psi, so it must ramp up somewhat with rpm to hit that pressure relief. Not sure what rpm that will happen at.
I think it would be reasonable to assume pressure proportional to rpm (all other things being equal), so 4.4 psi at 1050 rpm would need over 16000 rpm to reach 70-odd psi. So, maybe it's right that under normal operation more revs does give more pressure, it's only when cold that the pressure release valve operates. We can probably presume that the oil temperature doesn't rise significantly with sustained high rpm because it's cooled by the water coolant.
Well, after studying the manual I think I have made an incorrect assumption. I had thought that the coolant left the radiator (after being cooled) and entered the engine through the top tube that mounts to the valve cover and lowed down and out. It appears that this is incorrect and the coolant exits the engine through the tube set, then to the thermostat and then to the radiator.
