Hi Poormanagement,
earlier you said "I'm assuming that an ideal NA motor - let's say a 2.0L making 220hp is doing so
at the limits of the structure of the engine - for arguments sake, with cylinder pressures of 120 bar"
====================
Why would you assume that?
Although "making it through the warrantee" is an important requirement, manufacturers of successful products had better do a bit better than that.
In 2006 Toyota's basic Warrantee was 3 years 36,00o miles, and the powertain warrantee was 5 years 60,000 miles. If Toyotae had the rep for engine trouble at 65,000 miles I doubt they would have outsold Ford in the US that year.
I question if such pin-point engineering calculations even exists. If they did, it seems like it would have gone a long way to creating a world where there would be NO warrantee failures like the famous Ford Taurus automatic AX4S transmission pre 1995 aluminum clutch piston failure. (Most of those transmissions did survive beyond 60,000 miles). I find it interesting that most articles blame the failures on the aluminum piston's "cheapness", without any mention of how the replacement steel piston design or material properties differ.
There are tales that In the early days of drag racing hot rodders in emergencies would replace blown up engines with junkyard engine short blocks and compete successfully, for a few runs anyway. Some of those engines designed and developed without benefit of computer simulation were pretty stout.
Similarly, Every few months of 2014 it seemed there was an article in Hot Rod magazine, etc about taking a used V8 engine, sometimes from a
junkyard automotive recycler, sometimes without even disassembling and freshening the lower end, installing a supercharger on it, and squeezing 800 plus HP out of the poor thing on some dyno somewhere, at least long enough for a dyno sweep.
I'm thinking that original designs these days initially focus on things like resisting deflection under load and resistance to thermal cycling, and packaging concerns, so that straight "strength" may even be carried along nearly for free with analysis for resistance to fatigue or something similar.
I especially enjoy this comment by Unbrako on page 64 of their Engineering guide for the simple sounding calculation of thread engagement to resist tapped hole thread "stripping.".
"
Attempts to compute lengths of engagement and related factors by formula have not been entirely satisfactory-mainly
because of subtle differences between various materials. Therefore, strength data has been empirically developed from a series of tensile tests of
tapped specimens for seven commonly used metals including steel, aluminum, brass and cast iron."
