But air boxs are also designed to cut down noise on modern production motorcycles.
I expect noise probably IS inclusive of the overall design goal. But, I don't see that as evidence of a primary design goal. I feel confident in saying that overall performance in the majority of driving conditions, as well as peak performance in a confined application space, was a main selling goal for Honda. Does this mean some design trade-offs? I expect so.
For instance the Kawasaki 1500 classic (carbed), has 9 bends in the air box system before the air reaches the carb. One of the bends is 180º. Bends in the intake system slow the air down. That cuts down noise. Dyno runs have shown an increase in power when this air box system is eliminated.
OK, but that is a dyno run for a completely different design. Implying that two induction system designs behave in an identical manner, is rather like saying two glass containers hold the same amount of liquid, regardless of shape, size, or construction.
Besides, isn't the OP looking for dyno comparisons, before and after, on the SOHC4? I'd like to see those, too! (Particularly if the jetting was optimized both before and after the pod conversion.)
Plemnum chambers on fuel injection motorcycles is a completely different subject.
How is that different from the Kawasaki 1500, or the various forms of SOHC4 induction systems? (This is actually a rhetorical question just to draw attention to the basic comparison dissimilarity.)
Back in the day when these carbed CB750's were racing I never saw them with stock air boxes. I did not see any of the bikes with stock air boxes.
I hear/read this argument a lot. I assume the base assumption being that if it is good for a racer, it is good for a street bike. However, I feel the assumption fails in the majority of cases, imo.
What unlimited racer is not willing to sacrifice an engine that would normally run for 100,000 miles, if it would win him 5 races of 20 miles each?
How popular would a street bike offering be if the engine only lasted 100 miles between complete rebuilds? Racers routinely sacrifice the machine to win the prize. Is that really the model you wish to emulate? Are you racing? ...Or going on a road trip? Or, do you want to drive the machine to work and back for 5 (or more) years?
While there are some race mods that make the transference to production models, certainly not ALL race mods do. The mods may be task based, where that task is not routinely applied to, or needed for, a reliable general transportation vehicle.
I feel pretty confident in generalizing that the stock induction offers NO detriment to engine performance up to 2/3 (quite possibly much more) of the operational engine RPM band between idle and red line RPM. Would a race purposed bike be concerned much about this lower operational band?
Would a race purposed bike be willing to sacrifice 50% of performance bellow 2/3 of red line to make a 5% gain nearer to and above red line?
Would that same 5% gain coupled with a shorter engine life be accepted for a race purposed bike? If it lasts to end of race, the answer is mostly yes!
The point is, if you adopt any race bike mods, you also accept the trade off made for that mod.
I could make a conjecture that pods on race bikes became popular simply as a means for quicker jet size changes, in order to eek out max power for the altitude, barometric pressure, and temperature of the track where the race bike was being run.
If it was done solely for that purpose on a race bike, does it really make sense to put pods on a street bike for that same purpose? Can you imagine optimizing the jets and carb tune each day before going to work?
Still, I'd like to see reproducible data for the SOHC4, showing where a particular pod conversion has improved performance and in what RPM band it occurred.
Cheers,
