Great article Tim! I think tha author has a good grasp on the issues. Now we need to break it down to a specific car. In my case the FFR Coupe.
Here are the issues brought up by the stop-tech article:
1. "Weight distribution of the vehicle at rest". The brake system we use was designed for a very front heavy car. My Coupe has the same weight distribution as the Ferrari 458.
2. "CG height – the higher it is, the more weight gets transferred during a stop." My Coupe has a much lower CG height than the Mustang.
3. "Wheelbase – the shorter it is, the more weight gets transferred during a stop". Coupe is not much different in wheelbase.
4. Stiffness of suspension. Not addressed by the article, but plays a major role in weight transfer. A softly sprung car transfers much more weight due to the CG change caused by the diving of the front and the lifting of the rear. Ever see a old muscle car slam on the brakes and the rear bumper comes about 4' into the air. That is weight transfer caused by CG change.
5. "Typically, the auto manufacturers design their cars to be 5% to 10% more front-biased than optimum for maximum deceleration" On the track I am not willing to give up that extra 10% Ford built in for soccer moms.
6. "Your brakes do not stop your car. Your tires do stop the car." This does not apply to my Coupe with 315F/315R but does affect your roadsters with 255F/315R. The Mustangs never had this kind of tire imbalance. Just this factor alone accounts for a 20% difference front to rear in stopping power.
7. Driver capability - I am guessing that we as a group are much more capable drivers than the average soccer mom or beginning teenager. Why......because we are muscle car fanatics. We drive some of the most brutally fast cars ever made. We go looking for the edge of the envelope when most drivers cower from it.
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WEIGHT TRANSFER
Here some calculations I made comparing my coupe to a Mustang regarding weight transfer. These figures only account for point #1 above. The other 6 points are not considered.
url=http://phors.locost7.info/phors01.htm]Part 1: Weight Transfer[/url]
Comes from this:
Brian Beckman's Physics of Racing Series
His calculations:
"Lf = 1600 + 3200 / 5 = 2240 lbs, Lr = 1600 - 3200 / 5 = 960 lbs
Thus, by braking at one g in our example car, we add 640 pounds of load to the front tyres and take 640 pounds off the rears! This is very pronounced weight transfer."
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My calculations:
Lf = 1600 + 3200 / 5 = 960 lbs, Lr = 1600 - 3200 / 5 = -320 lbs
so 960 + -320 = 640 lbs?????
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So on my car:
Lf = 1080 + 2400 / 5 = 696 lbs, Lr = 1320 - 2400 / 5 = -216 lbs
so 696 + -216 = 480 lbs of weight transfer in my coupe if it had the same wheelbase, springs, and CG as the example which it does not.
That means my weights would then be 1560 front and 840 rear = 2400 total
Lf now is 1560 = .65% front
Lr now is 840 = .35% rear
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So on a Mustang that these brakes were designed for:
a 1998 SVT Cobra has 1950 Front and 1425 rear = 3375 total
Lf = 1950 + 3375/5 = 1065, Lr = 1425 - 3375 / 5 = -390
so 1065 + -390 = 675 lbs of transfer
Lf now is 2625 lbs = .78% front
Lr now is 750 lbs = .22% rear
Now there are some things to consider. Our cars are more stiff and have a much lower CG than a stock Mustang. You must also take into account the larger rear tires we use which will have more friction thus more stopping power.
IMPORTANT!!!!! Notice that in our brake pressure test we did on my Coupe the pressures were a 80%/20% split. Interesting that the laws of physics say in a 1G stop the SVT Cobra has a 78%/22% split in weight distribution. Also notice that the laws of physics say my Coupe is awfully close to that 60/40 split mentioned as a target for brake bias in the other article. Convinced yet!!!!!!
