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where engineers begin frothing at the mouth

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Mechanical advantage of the lever at the pedal, area ratio from the master to the caliper, lump capacitance of the fluid system / materials, torque on the wheel from the braking force, coefficient of friction at the pad rotor interface dependent on: brake pad material(s) - rotor material - rotor surface condition - pad surface condition - temperature - humidity, reaction torque from the tire road interface, coefficient of friction at the tire interface as a function of the slip ratio.. nooooo... let it goooo...


OK Kevin, I think I am OK now...

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Michael
AS in Automotive Technology (1990)
ASE Certified Master Tech (1991)
BS in Mechanical Engineering (1997)
MS in Mechanical Engineering w/ a concentration on Dynamic Systems and Controls (2005)

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Dividing by 4 brake pads gives you a total of .0041" of movement.

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Interesting - be nice to go out and slowly press the pedal with someone turning each wheel to see if this is indeed what happens. The only way around this would be separate master cylinders and a balance bar, you could then tune it to your liking.
...

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Excel file is available for download here:

http://www.3gduster.com/brakes.html

Enjoy!

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When I suggested in the other thread that it would be nice if this was all in an excel spreadsheet, I didn't think anyone would actually do it! I was thinking of trying to do it myself, but it would have taken a week, and I still would not have gotten it right.

Thanks to both of you for all the time you have put into this. This sheet has been downloaded, saved, and backed up for future reference.

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one bit of math missing here.

relationship of piston stroke in the M/C versus pedal ratio.

Someone here thinks less leverage is less stroke at the M/C

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one bit of math missing here.

relationship of piston stroke in the M/C versus pedal ratio.

Someone here thinks less leverage is less stroke at the M/C

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Less leverage is less stroke at the pedal. Stroke at the master is determined by the system downstream.

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one bit of math missing here.

relationship of piston stroke in the M/C versus pedal ratio.

Someone here thinks less leverage is less stroke at the M/C

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Look at the chart again.

The third input requested is pedal ratio. 7 in the example.
The sixth (and last) input requested is how far you moved the pedal. 5 inches in this example.

The third output listed is "the master cylinder moved this far". .7143" in this example.

There's your stroke by pedal ratio.


You referenced FD's power booster conversion. I specifically stated that the math in these examples was for a manual brake system only and that if you used a booster you were on your own.

If you want to get into pedal effort by master cylinder size, start punching numbers.
Put in a 1" master with 100 lbs pedal effort and see what the brake torque is.
Put in a 1-1/8" master with 100 lbs pedal effort and see what the brake torque is.
Start putting higher numbers in the pedal effort until you get back to the same brake torque.

Going from the example's 15/16" master cylinder to a 1-1/8" master cylinder shows that the pedal effort increases from 100 lbs to 144 lbs to get the same brake torque. A 44% increase in pedal effort is not going to make for a happy driver.

Go back and play with the numbers and see what the spreadsheet will do for you. It's kinda fun.

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I understand all that, but it' not as obvious as it might need to be for some.

Anyway, one other thing to consider when using your formulas is the capacity of the m/c and the needs of the calipers. Not enough volume out of the M/C and the calipers will not do the job, which is what I think FD had for a problem.

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I understand all that, but it' not as obvious as it might need to be for some.

Anyway, one other thing to consider when using your formulas is the capacity of the m/c and the needs of the calipers. Not enough volume out of the M/C and the calipers will not do the job, which is what I think FD had for a problem.

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I think we bore that out in the math.




The 15/16" master worked fine once he put the booster back in.

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Perhaps you could build some sort of electric brake controller that will vary the brake pressure based on speed, traffic conditions, and the presence of radar emissions directed at the vehicle.

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No more of this ABS stutter-stop stuff. Just lower the pressure in the event of wheel lockup. And/or change the rear pressure based on road speed and current load (for trucks). Should work great!