Is there a reason (other than budget) you don't want to use the forged wiseco's available from CycleX or APE?
Yes, a very good reason: the forged pistons are not (have never been) the best match for these engines, for a variety of reasons.
The forged pistons have an issue that's kind of hard to explain to the casual rider - when they are new, especially. The pistons expand and contract much more slowly than the cast type: the cast type are material-matched to the cylinders. Thus, with the forged ones, they slap loosely while the engine is warming them up, and when shut off, the cylinders shrink onto them tightly before they cool off. This causes some lube problems with the piston skirts, so the piston-makers tell you to increase the bore clearance to more than 2x the standard allowance. This, in itself, guarantees shorter ring life, and usually shorter piston life as well. (Reasons described below.)
After a fresh rebuild, a typical scenario is: the bike is fired up cold in the AM, then ridden maybe 2-3 miles to a gas station. After fueling (5 -ish minutes turned off), the electric start cannot turn over the engine to start, and the kickstarter feels locked. After another 10 minutes, the pistons cool off and shrink again, it starts up fine, and the perplexed novice rider wonders what happened to his freshly-rebuilt engine. (Then they come back to you, asking WTF?)
Here's what is happening while this is going on: first - understand that the oil film between the piston skirt and the cylinder wall is 93% of the cooling path for the piston (the remainder is the oil spray to the underside of the piston crown, being sprayed there by the rod bearing squirts). This clearance must be small so the oil can make a thin layer of full contact, otherwise the cooling "falls behind". In the forged-piston engines, e.g., Wiseco, this clearance is set at 0.0022"-0.0024" per their spec (CB750-size pistons), while cast pistons are 0.0008"-0.0012" (half as much). As the cylinders warm up, they grow rapidly (light aluminum-zinc alloy), while the denser forged aluminum heats up much slower. Once everything reaches operating temperatures together, all of these pistons have about the same operating clearances (near the minimum size), so the oil can interface the heat to the cylinder walls.
But...during each cold-to-hot cycle, the forged pistons' large clearance does not trap oil well and the pistons tend to scuff, usually much more than the cast pistons. In fact, I have seen 750 pistons with more than 60k miles on them with skirts that look new, while I have never seen forged pistons without scratched skirts, even with as few as a thousand miles on them. This scratch generates grit, which attacks the rings directly above them. It also allows too much oil to slip past the skirt, which puts increased pressure on the oil rings. If you examine forged pistons next to cast pistons, you will often find the return-oil holes (under the oil rings) to be larger, or more numerous, to lower this pressure. Some even have special arrangements, like chamfered holes, to improve on this situation. The oil that does not get scraped off by the oil rings then upsets the 2nd ring as the piston reverses during overlap, causing ring flutter: in real high-RPM engines this can cause ring fracture after a while.
In the above-mentioned scenario, the 'stuck' engine happens like this: the cold engine, ridden to the gas station, heats up the cylinders pretty quickly, while the forged pistons lag behind a little bit. Once the engine is stopped (before all parts have reached full temp), the cylinders cool quickly, the forged pistons not so much. This traps the oil that is on the piston skirts, hydraulically locking the piston(s) in place for a while. This then starts cooling off the pistons, so about 5-10 minutes later the engine can turn over again.
A classic example: read the debut of the CycleX "Super F2" bike's first race. This bike has (had?) forged pistons, big-bore size. The bike was ridden to the Line, then shut off a few minutes until the race Start was signalled. At that point, the engine was locked and the rider could not start it. The pit crew ran up and got it started (I think they used a rear-wheel roll starter?) and he went on to win the race.This is EXACTLY the symptoms. The article about this race blamed the lockup on "too much compression", but that's not what happened: even if it had 7:1 CR, it still would have acted the very same way.
So, after we raced with Powroll and Wiseco forged pistons long enough to learn these things, we quit using them for start-and-run (like LeMans start) races. I have never really understood the need for them in these engines unless either the compression is above 11:1 or a turbo/blower is implemented, anyway? I can understand them in a Ford 427 cubic inch, (dual) SOHC engine making over 850 HP at 8500 RPM, sure (those are 4.25" pistons!), but not in engines this small. For me, they are simply not worth the hassles, IHMO.
