Quote:
Originally Posted by Jim Caughlin
To answer your question pretty basically, your best 60' will be at as high of RPM as your tires and valve springs will hold.
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Jim's response above is a great answer to this thread's original question.
Torque x RPM, highest average number wins if you can get all that power to the track consistently. Raising launch rpm adds area under the engine's rpm trace, which means the engine will produce more power strokes in that critical first second after launch. The clutch's engagement characteristics are among the most important adjustments you can make to a stick shift drag car, both for the launch as well as after the shifts.
If you have a typical diaphragm, B&B, or non-adjustable Long style pressure plate that uses spring pressure only (no centrifugal assist), the engine rpm drawdown part of the engine rpm trace will be pretty linear, basically a straight line like on this graph below...
If you have a SoftLok style "adjustable slipper clutch" that uses counterweights in addition to spring pressure to clamp the disc, the part of the engine rpm trace where that clutch pulls the engine down will form a gradual curve. Because its centrifugal counterweight component relaxes as the clutch pulls engine rpm down, overall clutch clamp pressure relaxes as well. Note that engine rpm initially drops very quickly after the gear change (trace falls almost straight down), but then the trace begins to gradually curve as the clutch gradually loses it's ability to pull the engine down any further...
One feature of the curved engine rpm drawdown shape is that it adds area under the engine's rpm trace. If the above clutch had not slipped at all after the 1/2 shift, the ratio change dictates it would have pulled the engine down to around 5245rpm (input shaft speed) after the tires hooked back up. But because it was a SoftLok style clutch with a centrifugal component, clamp pressure relaxed as the engine lost rpm, which in-turn slowed down the rpm loss. Because the car was also gaining speed while the clutch was slipping, the delayed lockup point raised the minimum rpm after the shift to 6302 instead of drawing the engine all the way down to 5245rpm as predicted by the ratio change. That added clutch slip time tightened up the engine rpm operating band, which in-turn allows the engine to operate higher on the plateau of its HP curve.
Going back to the static-only (no centrifugal assist) clutch graph below, another thing to note is that you can adjust the angle of engine rpm drawdown on the graph by adjusting the clutch's static clamp pressure. Note that angle of the drawdown after both shifts on the below graph are basically the same, while the drawdown angle after launch is still straight but the rpm is drawn out over a longer time period...
The above difference in drawdown angles was made possible by externally controlling throwout bearing position during launch. Basically the throw-out bearing was not allowed to fully retract during launch, which prevented the full force of the clutch's spring pressure from clamping the disc. The throw-out bearing was then allowed to retract shortly after launch, which in-turn increased the clutch clamp pressure available for the shifts. The angle of the drawdown during launch is adjusted via throw-out bearing position, the angle of the drawdown after the shifts is adjusted via static clamp pressure. You end up with more clutch slip during launch, less clutch slip after the shifts.
Here's the SoftLok style curved drawdown shape compared to a straight drawdown after the shifts...
Notice how an adjustable static-only (no centrifugal assist) straight-line drawdown can be optimized to add even more area under the engine's rpm trace than the traditional SoftLok style curved drawdown. Also note that the initial draw down after the shift is not as steep. That flatter angle indicates energy is leaving the engine's rotating assy at a slower rate, which in-turn makes it easier to keep the tires stuck thru the shift. Because the engine is producing power at a quicker rate during the straight-line drawdown, clutch lockup occurs sooner which allows the engine to get a head start on its climb to the next shift point.
When you add external throw-out bearing position control to the static only (no centrifugal assist) straight-line drawdown, you end up with a more consistent dead-hook launch that doesn't drag the engine down. It also really shines on a crappy track. The dead hook reduces the need to adjust tire pressure and launch rpm for the purpose of controlling wheelspeed. Without the need to control wheelspeed, you will likely be able to make use of less first gear ratio, which will in-turn allow tightening up the gear splits. Little gains here and there, but it all adds up.
It's a lot like the quick automatic transmission cars. A less efficient coupling allows the engine launch higher and gain rpm faster while also reducing rpm loss after the shifts. The increase in power production shows up as more area under the engine rpm trace, and that added power more than offsets the loss of mechanical efficiency.
In my opinion, in most cases the traditional SoftLok "adjustable slipper clutch" style clutch tune is becoming out-dated tech. First it limits your ability to take advantage of launch rpm, then it has a tendency to knock the tires loose after the shifts. Knocking the tires loose after the shifts is usually what prevents guys from making the switch to radials.