Let's talk about lightweight clutch/Flywheel combo's
#221
#222
Haha I had a feeling you'd post something Good Hio. Car sounds amazing with the new exhaust! Being that you have probably the lightest clutch assembly, do you think the driver for the tach is accurate in keeping up with the actual rpm on freerev or lower gears? I've heard that the tach readout can't keep up sometimes. Did it take much for you to dial your idle back in after the clutch install?
I'd love to have your faceplated trans and clutch with a S1 sequential shifter and pressure sensitive shift ****. It would be as close to a full on Emco or similar.
I'd love to have your faceplated trans and clutch with a S1 sequential shifter and pressure sensitive shift ****. It would be as close to a full on Emco or similar.
#224
I had two engines that were pretty close to the same but different component weights. I didn't change the weight of the flywheel/clutch itself, but i did change the weight of the overall rotating assembly...
...Engine #1 was 4.04" x 3.48" w/ 5.7" i-beam rods, hypers with gas ported spacers and 1.2mm rings (12lb oil), 49lb crank balanced to a 1863g bobweight.
...Engine #2 is 4.03" x 3.48" w/ 6" aluminum rods, forged pistons with lateral gas ports and 1.5mm rings (14lb oil), 42lb crank balanced to a 1492g bobweight with pendulum style counterweights, drilled rod journals.
Both have flat tops with nearly identical quench and compression. Same intake and carb, same carb calibration. Exact same cam installed on the exact same intake centerline. Same flywheel and pressure plate installed in exactly the same car, same weight, with exactly the same gearing and tires. Even though these tests were a couple weeks shy of 2 years apart, both tests are on the same location with zero tire spin and conditions were very close to the same.
Here's the observed rates that the engines gained rpm WOT...
1st gear 2000 to 4000 rpm- engine #1 1634 rpm/sec........engine #2 1910 rpm/sec (276 rpm/sec difference)
1st gear 4000 to 6000 rpm- engine #1 1975 rpm/sec........engine #2 2217 rpm/sec (242 rpm/sec difference)
2nd gear 4000 to 6000 rpm- engine #1 1070 rpm/sec.......engine #2 1116 rpm/sec (46 rpm/sec difference)
3rd gear 4000 to 6000 rpm- engine #1 535 rpm/sec.........engine #2 541 rpm/sec (6 rpm/sec difference)
As you can see, in the higher gears where acceleration is slower there is not much difference in acceleration rate. But in the lower gears, the differences in rate of acceleration progressively increase.
There also seems to be a quite a difference in no load acceleration rate, but the conditions of the comparison were not the same. I had a clutch linkage experiment go bad in 2014 with engine #1, which resulted in a free-rev condition during a 4000 rpm WOT launch in which that engine gained rpm at an 8500 rpm/sec rate. I was also experimenting with pulling timing at the time for a no-prep race, but my records don't indicate that i was pulling timing on that particular launch.
Under NA free-rev conditions, engine #2 gains rpm at a 11,515 rpm/sec rate.
All acceleration tests are basically inertia dyno runs, even if that test is a no-load test where the only inertia resistance is supplied by the weight of the rotating assy itself. What most people lack is a way to collect accurate comparable data. Even though these tests were conducted almost 2 years apart, the car itself was basically a time capsule...engine #1 blew up a few weeks after the test, and i had other irons in the fire so the car sat until engine #2 was ready to install. I was just picking up where i left off with regard to developing the car. To me the part that says it's because of the lighter rotating assy is because the closer the two engines got to steady state power production, the closer the power outputs were. By 3rd gear, there was only a 6 rpm/sec difference. Sorry, no 4th gear data available to compare from engine #1, that test area just isn't long enough.
...Engine #1 was 4.04" x 3.48" w/ 5.7" i-beam rods, hypers with gas ported spacers and 1.2mm rings (12lb oil), 49lb crank balanced to a 1863g bobweight.
...Engine #2 is 4.03" x 3.48" w/ 6" aluminum rods, forged pistons with lateral gas ports and 1.5mm rings (14lb oil), 42lb crank balanced to a 1492g bobweight with pendulum style counterweights, drilled rod journals.
Both have flat tops with nearly identical quench and compression. Same intake and carb, same carb calibration. Exact same cam installed on the exact same intake centerline. Same flywheel and pressure plate installed in exactly the same car, same weight, with exactly the same gearing and tires. Even though these tests were a couple weeks shy of 2 years apart, both tests are on the same location with zero tire spin and conditions were very close to the same.
Here's the observed rates that the engines gained rpm WOT...
1st gear 2000 to 4000 rpm- engine #1 1634 rpm/sec........engine #2 1910 rpm/sec (276 rpm/sec difference)
1st gear 4000 to 6000 rpm- engine #1 1975 rpm/sec........engine #2 2217 rpm/sec (242 rpm/sec difference)
2nd gear 4000 to 6000 rpm- engine #1 1070 rpm/sec.......engine #2 1116 rpm/sec (46 rpm/sec difference)
3rd gear 4000 to 6000 rpm- engine #1 535 rpm/sec.........engine #2 541 rpm/sec (6 rpm/sec difference)
As you can see, in the higher gears where acceleration is slower there is not much difference in acceleration rate. But in the lower gears, the differences in rate of acceleration progressively increase.
There also seems to be a quite a difference in no load acceleration rate, but the conditions of the comparison were not the same. I had a clutch linkage experiment go bad in 2014 with engine #1, which resulted in a free-rev condition during a 4000 rpm WOT launch in which that engine gained rpm at an 8500 rpm/sec rate. I was also experimenting with pulling timing at the time for a no-prep race, but my records don't indicate that i was pulling timing on that particular launch.
Under NA free-rev conditions, engine #2 gains rpm at a 11,515 rpm/sec rate.
All acceleration tests are basically inertia dyno runs, even if that test is a no-load test where the only inertia resistance is supplied by the weight of the rotating assy itself. What most people lack is a way to collect accurate comparable data. Even though these tests were conducted almost 2 years apart, the car itself was basically a time capsule...engine #1 blew up a few weeks after the test, and i had other irons in the fire so the car sat until engine #2 was ready to install. I was just picking up where i left off with regard to developing the car. To me the part that says it's because of the lighter rotating assy is because the closer the two engines got to steady state power production, the closer the power outputs were. By 3rd gear, there was only a 6 rpm/sec difference. Sorry, no 4th gear data available to compare from engine #1, that test area just isn't long enough.
#225
The real fact of the matter is that even a very light flywheel, after vehicle weight and all gearing is taken into account will make negligible difference in most cars.
The lighter the vehicle the more chance of a difference, likewise with the shorter the gearing.
And little of that applies to any of these cars as most gearing is still fairly tall and few are very light.
The lighter the vehicle the more chance of a difference, likewise with the shorter the gearing.
And little of that applies to any of these cars as most gearing is still fairly tall and few are very light.
#226
Haha I had a feeling you'd post something Good Hio. Car sounds amazing with the new exhaust! Being that you have probably the lightest clutch assembly, do you think the driver for the tach is accurate in keeping up with the actual rpm on freerev or lower gears? I've heard that the tach readout can't keep up sometimes. Did it take much for you to dial your idle back in after the clutch install?
I'd love to have your faceplated trans and clutch with a S1 sequential shifter and pressure sensitive shift ****. It would be as close to a full on Emco or similar.
I'd love to have your faceplated trans and clutch with a S1 sequential shifter and pressure sensitive shift ****. It would be as close to a full on Emco or similar.
When your on it the tach us pretty far off till 3rd gear. In that vid it's back to idle before the tach is.
I did no actual idle tuning besides raising idle speed to 800rpm. Now what i did do to help with drivability was turn off the throttle cracker.
I had two engines that were pretty close to the same but different component weights. I didn't change the weight of the flywheel/clutch itself, but i did change the weight of the overall rotating assembly...
...Engine #1 was 4.04" x 3.48" w/ 5.7" i-beam rods, hypers with gas ported spacers and 1.2mm rings (12lb oil), 49lb crank balanced to a 1863g bobweight.
...Engine #2 is 4.03" x 3.48" w/ 6" aluminum rods, forged pistons with lateral gas ports and 1.5mm rings (14lb oil), 42lb crank balanced to a 1492g bobweight with pendulum style counterweights, drilled rod journals.
Both have flat tops with nearly identical quench and compression. Same intake and carb, same carb calibration. Exact same cam installed on the exact same intake centerline. Same flywheel and pressure plate installed in exactly the same car, same weight, with exactly the same gearing and tires. Even though these tests were a couple weeks shy of 2 years apart, both tests are on the same location with zero tire spin and conditions were very close to the same.
Here's the observed rates that the engines gained rpm WOT...
1st gear 2000 to 4000 rpm- engine #1 1634 rpm/sec........engine #2 1910 rpm/sec (276 rpm/sec difference)
1st gear 4000 to 6000 rpm- engine #1 1975 rpm/sec........engine #2 2217 rpm/sec (242 rpm/sec difference)
2nd gear 4000 to 6000 rpm- engine #1 1070 rpm/sec.......engine #2 1116 rpm/sec (46 rpm/sec difference)
3rd gear 4000 to 6000 rpm- engine #1 535 rpm/sec.........engine #2 541 rpm/sec (6 rpm/sec difference)
As you can see, in the higher gears where acceleration is slower there is not much difference in acceleration rate. But in the lower gears, the differences in rate of acceleration progressively increase.
There also seems to be a quite a difference in no load acceleration rate, but the conditions of the comparison were not the same. I had a clutch linkage experiment go bad in 2014 with engine #1, which resulted in a free-rev condition during a 4000 rpm WOT launch in which that engine gained rpm at an 8500 rpm/sec rate. I was also experimenting with pulling timing at the time for a no-prep race, but my records don't indicate that i was pulling timing on that particular launch.
Under NA free-rev conditions, engine #2 gains rpm at a 11,515 rpm/sec rate.
All acceleration tests are basically inertia dyno runs, even if that test is a no-load test where the only inertia resistance is supplied by the weight of the rotating assy itself. What most people lack is a way to collect accurate comparable data. Even though these tests were conducted almost 2 years apart, the car itself was basically a time capsule...engine #1 blew up a few weeks after the test, and i had other irons in the fire so the car sat until engine #2 was ready to install. I was just picking up where i left off with regard to developing the car. To me the part that says it's because of the lighter rotating assy is because the closer the two engines got to steady state power production, the closer the power outputs were. By 3rd gear, there was only a 6 rpm/sec difference. Sorry, no 4th gear data available to compare from engine #1, that test area just isn't long enough.
...Engine #1 was 4.04" x 3.48" w/ 5.7" i-beam rods, hypers with gas ported spacers and 1.2mm rings (12lb oil), 49lb crank balanced to a 1863g bobweight.
...Engine #2 is 4.03" x 3.48" w/ 6" aluminum rods, forged pistons with lateral gas ports and 1.5mm rings (14lb oil), 42lb crank balanced to a 1492g bobweight with pendulum style counterweights, drilled rod journals.
Both have flat tops with nearly identical quench and compression. Same intake and carb, same carb calibration. Exact same cam installed on the exact same intake centerline. Same flywheel and pressure plate installed in exactly the same car, same weight, with exactly the same gearing and tires. Even though these tests were a couple weeks shy of 2 years apart, both tests are on the same location with zero tire spin and conditions were very close to the same.
Here's the observed rates that the engines gained rpm WOT...
1st gear 2000 to 4000 rpm- engine #1 1634 rpm/sec........engine #2 1910 rpm/sec (276 rpm/sec difference)
1st gear 4000 to 6000 rpm- engine #1 1975 rpm/sec........engine #2 2217 rpm/sec (242 rpm/sec difference)
2nd gear 4000 to 6000 rpm- engine #1 1070 rpm/sec.......engine #2 1116 rpm/sec (46 rpm/sec difference)
3rd gear 4000 to 6000 rpm- engine #1 535 rpm/sec.........engine #2 541 rpm/sec (6 rpm/sec difference)
As you can see, in the higher gears where acceleration is slower there is not much difference in acceleration rate. But in the lower gears, the differences in rate of acceleration progressively increase.
There also seems to be a quite a difference in no load acceleration rate, but the conditions of the comparison were not the same. I had a clutch linkage experiment go bad in 2014 with engine #1, which resulted in a free-rev condition during a 4000 rpm WOT launch in which that engine gained rpm at an 8500 rpm/sec rate. I was also experimenting with pulling timing at the time for a no-prep race, but my records don't indicate that i was pulling timing on that particular launch.
Under NA free-rev conditions, engine #2 gains rpm at a 11,515 rpm/sec rate.
All acceleration tests are basically inertia dyno runs, even if that test is a no-load test where the only inertia resistance is supplied by the weight of the rotating assy itself. What most people lack is a way to collect accurate comparable data. Even though these tests were conducted almost 2 years apart, the car itself was basically a time capsule...engine #1 blew up a few weeks after the test, and i had other irons in the fire so the car sat until engine #2 was ready to install. I was just picking up where i left off with regard to developing the car. To me the part that says it's because of the lighter rotating assy is because the closer the two engines got to steady state power production, the closer the power outputs were. By 3rd gear, there was only a 6 rpm/sec difference. Sorry, no 4th gear data available to compare from engine #1, that test area just isn't long enough.
I noticed the same weedy. The biggest gains are in the first 2 gears because of less load on the motor. The clutch cannot change actual engine power but it can change the rate of acceleration of the engine. And last i check we don't race hp.....we race acceleration.
I think gm was trying to dumb down acceleration a bit in the first couple gears wuth these heavy *** clutch/fly set ups to help people maintain control of thr cars. Maybe some other reasons to but a heavy clutch/fly set up for sure hurts the 1/2 gear the most. We noticed in lazerlemons 5gen that the car just kinda seemed to accelerate the same in the first 2 gears no matter what we did. 3rd seemed to pull harder than 1st or 2nd because the motor was actually loaded. You could feel it better. We deemed it was because the motor was basically accelerating that heavy *** clutch/fly as fast as it could no matter what. Other vids of 5gens seem to confirm that.
If we can capture that momentum in the 1/2 gears it should help it. Of course I've ran this type of clutch for years now. Is it for everyone. ...no. but if you can make it work for its a decent mod for a ls. It really lets all the tq they make be felt.
Stevie is on point to. Although it seemed to make a difference in this 5gen. It's heavy and not geared as aggressive as it should be. His car is about 600lb heavier than mine.
Hammers car sounds so good!
Last edited by HioSSilver; 03-03-2017 at 10:34 AM.
#228
Well....if you didn't ignore weedy's factual information then you would know that it's not equivalent to louder exhaust. Keep in mind he is talking about a 7lb difference. I'm talking about a 40lb difference with a massive change in moi.
I was merely trying to point out that this is not some lightweight car with a ton of gear......lol :/
I was merely trying to point out that this is not some lightweight car with a ton of gear......lol :/
#229
Well....if you didn't ignore weedy's factual information then you would know that it's not equivalent to louder exhaust. Keep in mind he is talking about a 7lb difference. I'm talking about a 40lb difference with a massive change in moi.
I was merely trying to point out that this is not some lightweight car with a ton of gear......lol :/
I was merely trying to point out that this is not some lightweight car with a ton of gear......lol :/
#230
1st gear 4-6k = 12.2% gain
2nd gear 4-6k = 4.2% gain
3rd gear 4-6k = 1.1% gain
These are gains in acceleration rate for the entire car on an actual road. Those engines might make around 500ft/lbs running steady state NA, making that 12.2% gain in 1st gear from 4-6k roughly equal to around 60hp.
#233
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From: Roseville, CA
I've had the Spec mini twin for about 2 months now. At first I thought it was a huge mistake being the car is my daily driver. I wasn't prepared for how stiff the pedal was going to be. Car was a pain in the *** to drive. Then it started stalling to the point I had to keep giving it throttle. Wasn't too happy.
Fast forward to now... I changed the master to a 5/8 bore and that made a world of difference. I can actually slip it and taking off is much easier. When warm it doesn't chatter much at all. The more I beat on it the better it drives. I also bought HPTuners and with the help of darth_V8 I got th tune dialed in perfect. All and all it's my favorite mod to date.
Fast forward to now... I changed the master to a 5/8 bore and that made a world of difference. I can actually slip it and taking off is much easier. When warm it doesn't chatter much at all. The more I beat on it the better it drives. I also bought HPTuners and with the help of darth_V8 I got th tune dialed in perfect. All and all it's my favorite mod to date.
#236
I think its only tough on a stock ECM, using Holley EFI with a big cam and lightweight clutch it was a few minor tweaks and it idles solid and returns to idle fine. Granted I think some of you have even lighter setups but a normal 7.25" Tilton triple wasn't so bad, the whole clutch is almost 10lbs lighter then the Monster flywheel I took out. The difference is stunning, my car used to rev like an old pickup truck, now the throttle response is insanely crisp. On top of that the shift feel is just awesome, so much better then I ever envisioned as it cleanly releases with less pedal throw.
#237
Mine was easy. For a while i did nothing really. It was basically fine but could use a little nicening. So i raised the idle a bit and turned off the throttle cracker. That ended up being better changes than i initially thought.
#239
I'm at 19 degrees idle timing, 925 RPM with a 231/239 cam on a 5.3L, I have a cable throttle I tossed that DBW junk in the trash.
Has anyone pushed these little triples past 1000whp reliably? I do like the cheap rebuild cost, but also don't want to have to pull the trans after every weekend of beating on it.
Has anyone pushed these little triples past 1000whp reliably? I do like the cheap rebuild cost, but also don't want to have to pull the trans after every weekend of beating on it.
#240
I think they are rated at over 700 for my 5.5 triple. A 7.25 could be more. But likely these are real #s that will take more instead of some of these clutch companies saying one thing and the clutch not holding it.