We were dealing with a 60% flow ratio exhaust to intake. In my world, the lobes I used are "endurance" lobes. This thing should make alot of laps and some street miles with no trouble. I would have approached it differently if we had brazed the floors in the exhaust, and/or had a real aggressive camshaft. I was using the split duration, tight centers, and the header/collector to crutch the 60% exhaust problem. My gut tells me that it would be hard to overscavenge this combo. If it had 75-80% exhaust ports, you would have seen a much different camshaft. I also had pump gas on my mind. The cam being pretty mild on the intake side, I tightened the centers to take some of the bite away from the DCR, which was fairly high for static of 11.3. I know the DCR calculators don't address the separation, but more overlap will reduce the tendency to detonate at lower rpm. Many factors led me to make the cam like this, and it did okay. R&D with no budget constraints could no doubt produce better results, but I had no 500" road race TP data to draw from, so this was square one.......
Got it, and certainly don't think I am critiquing. If it looks that way I apologize. It's an awesome build that did everything right.
I just brought it up because there is a lot of information out there on intake lobe selection, but exhaust tends to be more of a black art, although your discussion of using the headers to work the port shows you surely get it.
What I have been trying to wrap my head around is a way to increase intake duration while keeping the torque curve as flat as possible.
My theory is a very early and large intake lobe for these strokers, but to keep from excessive overlap, I want to find a fast way to empty the chamber with a faster exhaust lobe.
Ford actually did it in some of their motors, like the J code 302. The issue I m running into is without dyno testing, its all a WAG, add to it there is very little exhaust lobe discussion, I am no engineer, but it seems like without a requirement to keep anything in suspension, overspeeding an exhaust port is less critical, so we may as well get into the lift area for max flow as soon as we can
What I can't figure out is how to time that lobe, because ultimately, the opening of that lobe will determine how big I can experiment with an intake lobe.
I know it sounds backwards, and I truly understand standard cam design, but I really want to estimate then prove or disprove an experiment.
For example. (These numbers came out of my a$$ before I finished my first coffee BTW)
Cam 1 - standard kind of cam Intake 290/250/.650 lift, exhaust 294/254/.660 lift, 110 centers on 106 ICL
Intake closing point is at 71 ABDC, overlap is 72 degrees adv, at .050 overlap is 32 degrees
Cam 2 - Intake
300/258/.650 lift, exhaust 292/254/
.690 lift, 112 centers on 101 ICL
Intake closing point and overlap is the same, but looking for lift to evacuate the cylinder not duration.
While I was coming up with an example, I think what I am finding is to do what I want, I need to spread the centers and run a very early lobe to keep comparable numbers. In addition, to make a significant increase in lift, I may not have a streetable lobe on the exhaust side (as you pointed out)
Moreover, I am not sure that my end result between those two cams I put up as examples would make that much difference anyway LOL
Opinions?
