vorticism wrote: ↑01 Jan 2026, 17:59
wuzak wrote: ↑01 Jan 2026, 03:08
vorticism wrote: ↑31 Dec 2025, 20:06
Depends on what the goal is.
Maximum efficiency/power is the goal.
If the heat lost to coolant is reduced, there is more energy left to turn the crankshaft.
Yet aluminium is almost always chosen for head construction. Did thousands of engineers forget first principals? Or were there other goals beyond what you’re calling “the” goal?
"Thousands of engineers" had to work around low octane fuels and less advanced combustion technologies.
And work within a budget - not just for development, but for production.
vorticism wrote: ↑01 Jan 2026, 17:59
The post I had replied to claimed that steel heads are more prone to knock. Fair enough. That’s a common understanding of ferrous alloy heads, that regions of their CCs get too hot and cause autoignition. I offered him solutions for that as it would apply to a Formula One engine under these regulations. Forge the head to achieve sufficiently thin walls (to manage convection latency), machine features, weld a cam carrier onto it (must be one monolithic component and weldments seem to be permitted on the head), machine again, etc. Dial in the coolant flow rate to achieve CC wall temperatures similar to Al. The goal would be to end up with a head that has similar mass and structural properties which provides a more familiar, Al-like CC surface temperature, with the added benefit of the durability of steel (fatigue, surviving detonation wave fronts). Heat rejection would be identical to an Al head. If you need to solve a real world problem (f.e. make a Fe-alloy head which exhibits Al CC temps within the same performance domain), you have to make design choices that will solve it. Chanting first principals axioms while hoping for the best won’t get you very far.
I would say that iron-alloy heads tended to be older designs. Not really past the 1960s and 1970s, or maybe the 1980s.
And tended to be cast iron, rather than forged and machined steel.
The same could be said of pistons.
They went to aluminium a long time ago, even when the block and head(s) were cast iron. And a lot of effort went into finding aluminium alloys and coatings that allowed aluminium pistons to run in aluminium blocks, without using steel sleeves. Though many (most?) manufacturers opted for the steel sleeve in aluminium block solution.
But the 2026 F1 rules require a one of three specific steel alloys for the piston.
It may be for durability, but it also could be for other reasons.
The rumours are that the steel cylinder head for the Ferrari would be 3d printed. That would enable them to optimise where the material is and reduce weight.
vorticism wrote: ↑01 Jan 2026, 17:59
If the design intent from the outset is to use less cooling and allow hotter CC surface temps, then your insistence makes sense and I agree with you, but that wasn’t the intention of my post. A combustion concept which takes advantage of an intentionally hotter steel CC surface does open up interesting design paths f.e. potentially eschewing water coolant for oil or air. The thermal limits of inserts and “dismountable components” (spark plug, injector, pressure sensor, poppets) will need to be accommodated.
Less cooling = less drag.
They will opt for the least amount of cooling they can get away with regardless of engine type.
Sometimes they get it wrong, or the air temperature is higer than expected, and have to run lower power to compensate.
I doubt air or oil cooling are options, or desired. Air cooling would be difficult to achieve the required air flow around the heads.
The coolant system must be fitted with a pressure relief valve with a maximum setting of 3.75 bar gauge. That would give a boiling point of around 150°C for water.
That would, I think, exclude air cooling.
"Drag Power" = aero drag