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Ok, my end goal was to try to calculate the handling balance of the car with different sway bars in the front and back. That is, for a particular sway bar set, what's the weight on the front and back wheels through a corner? We need more than just how stiffer the front and rear bars are to figure this out. Excel helps too [img]smile.gif[/img]
Here's what I did:
1. Calculate the stiffness of each sway bar. From Fred Puhn's "How to Make Your Car Handle" (read this book!!) we have:
K (lbs/in) = 500,000 D^4/((0.4244xA^2xB) + (0.2264xC^3))
D = Dia bar
B = Length of center section
A = Length of end perpendicular to B (torque arm) C = Length of each end
This formula assumes solid bars, but hollow bars are within 10%. I have new bars in my living room, so I measured those.
2. Our front and rear spring rates figure into this as well. Numbers pulled from the tech database.
3. But at the front, the springs and sway don't act at the wheel, they're further up the pivot point. This lever action scales down the force. Measuring off some nice pics (fbodyextreme wilwood brake install), the springs act about 50% of the rate and the front sway is closer to 70%.
4. The solid rear axle means pretty much all the sway and spring rates are felt.
5. Now we add up the scaled front forces for spring and sway, and compare them to the rear spring and sway. Numbers expressed are the percent of total spring force on the front = front/(front+rear)
With stock late V6 springs (257/114 front/rear) we get:
With the 400/150 springs Sam Strano suggested for me (autocrossing), we have:
Of course, there's a lot of assumptions going on which affect the results:
1. Torsional body flex will tend to move the balance closer to 50/50, lowering these numbers
2. These numbers represent the front/rear division of the weight transferred to the outside tires in a corner. They don't count the static front/rear weight distribution, which at around 57/43, will raise these numbers a bit
3. I mentioned the difference in solid/hollow sway stiffness difference already.
4. Bushings and endlinks make a big difference in sway bar performance. Puhn's book mentions a .8" solid bushing bar acting the same as a 1" rubber bushing bar.
5. My measurements on the front scaling factors are estimates from an image file. If someone went under their car and took real measurements on this, they'd be more accurate.
So, what can we see from this?
1. On any spring, changing out the front sway without touching the rear puts a lot of extra weight on the front tires. While the increased camber control will increase front traction, you're still going to push pretty bad when you hit the limit.
2. The 32/19 combo looks like it'll act pretty much the same as the stock 28/15.
3. It's going to come to personal preference. Some people love to power out of the corners, and thus should stick to a higher front%. Moving the car more towards neutral means you can't floor it out of a corner, more touch is needed. But, moving the weight towards neutral means you'll be able to take the corner at a higher speed, making up that difference and possibly coming out ahead.
Now, let's see some discussion - I know everyone has opinions on what they like. How can I make the numbers better and more realistic? What am I missing? I'd like to refine this to the point where it's a standard thread in the Technical Archive.
-Jeff
[ November 20, 2003: Message edited by: zlexiss ]</p>
Here's what I did:
1. Calculate the stiffness of each sway bar. From Fred Puhn's "How to Make Your Car Handle" (read this book!!) we have:
K (lbs/in) = 500,000 D^4/((0.4244xA^2xB) + (0.2264xC^3))
D = Dia bar
B = Length of center section
A = Length of end perpendicular to B (torque arm) C = Length of each end
This formula assumes solid bars, but hollow bars are within 10%. I have new bars in my living room, so I measured those.
2. Our front and rear spring rates figure into this as well. Numbers pulled from the tech database.
3. But at the front, the springs and sway don't act at the wheel, they're further up the pivot point. This lever action scales down the force. Measuring off some nice pics (fbodyextreme wilwood brake install), the springs act about 50% of the rate and the front sway is closer to 70%.
4. The solid rear axle means pretty much all the sway and spring rates are felt.
5. Now we add up the scaled front forces for spring and sway, and compare them to the rear spring and sway. Numbers expressed are the percent of total spring force on the front = front/(front+rear)
With stock late V6 springs (257/114 front/rear) we get:
With the 400/150 springs Sam Strano suggested for me (autocrossing), we have:
Of course, there's a lot of assumptions going on which affect the results:
1. Torsional body flex will tend to move the balance closer to 50/50, lowering these numbers
2. These numbers represent the front/rear division of the weight transferred to the outside tires in a corner. They don't count the static front/rear weight distribution, which at around 57/43, will raise these numbers a bit
3. I mentioned the difference in solid/hollow sway stiffness difference already.
4. Bushings and endlinks make a big difference in sway bar performance. Puhn's book mentions a .8" solid bushing bar acting the same as a 1" rubber bushing bar.
5. My measurements on the front scaling factors are estimates from an image file. If someone went under their car and took real measurements on this, they'd be more accurate.
So, what can we see from this?
1. On any spring, changing out the front sway without touching the rear puts a lot of extra weight on the front tires. While the increased camber control will increase front traction, you're still going to push pretty bad when you hit the limit.
2. The 32/19 combo looks like it'll act pretty much the same as the stock 28/15.
3. It's going to come to personal preference. Some people love to power out of the corners, and thus should stick to a higher front%. Moving the car more towards neutral means you can't floor it out of a corner, more touch is needed. But, moving the weight towards neutral means you'll be able to take the corner at a higher speed, making up that difference and possibly coming out ahead.
Now, let's see some discussion - I know everyone has opinions on what they like. How can I make the numbers better and more realistic? What am I missing? I'd like to refine this to the point where it's a standard thread in the Technical Archive.
-Jeff
[ November 20, 2003: Message edited by: zlexiss ]</p>
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