jjn9128 wrote: ↑03 May 2018, 11:14
Aaah yes. It's hard enough staying on top of the detail of the current rule book sometimes, let alone remembering back 25-30 odd years
There's the bit in Newey's book where he talks about that vane he exploited from the bottom og the vortex tunnel down to the reference plane - aft of the front axle line - in 1993. The 50mm height must have been from 1995 when the step plane was introduced!?
Yes, that sounds about right. In 1995 the front wing was still at 40mm above the ref plane but the 50mm stepped bottom was introduced.
You said earlier:
jjn9128 wrote: ↑29 Apr 2018, 13:52
The problem is you can't force teams to unlearn what they've learned. In the late 90's CFD was still in relative infancy, so the majority of aerodynamic testing was performed in wind tunnels or on track (testing was unlimited back then). The advantage of CFD is being able to visualize the flow field around the car - which is where teams started playing with vortices to influence the rest of the car. Having that extra detail is when the car's started to sprout the extra aerodynamic features - as the teams really started manipulating and controlling the air around the car for net gains. The regulations between 2016 and 2017 weren't all that different really, conceptually, basically the car's were stretched to make them wider - the longer diffuser and wider rear wing were the main differences (for the design concept).
This for me is one of the problems when it comes to following another car - the flow field is so finely tuned that any disturbance will negatively impact performance. On top of the base effect of the wake - which is a dynamic pressure effect. Cleaner cars are generally easier to follow as spec series show - F2, Indycar, Superformula, Formula E... etc all have lower downforce than F1, but also cleaner aerodynamic surfaces.
That's an interesting point that a few others have mentioned and I may be wrong in my thinking but I do wonder............:
1) In the late 80's and early 90's, CFD and aero development was nowhere near the sophistication that we see today, so the cars back then by comparison weren't particularly optimised. Today's cars due to highly complex air flow management systems, enable downforce producing bodywork to receive very clean, highly energised flow, so in clean air a huge proportion of bodywork actually receives clean air.
With earlier designs (late 80's to early 90's for example), airflow management was far more rudimentary, meaning those individual cars
would essentially run in their own dirty wake, even when in so called clean air (no other car ahead for some distance), at least more so than today. Because of this, aerodynamicists of that era would be forced to deal with less than ideal airflow characteristics from the inception of a design, so while being in the slipstream of another car would still hurt aero, the fact that the design is not so critical on receiving clean air, could translate to better relative performance in dirty air.
Perhaps limiting wake management systems would be the best method of forcing teams to adopt designs more suited to working in less than ideal flow conditions?
2) There is also a move to ban front (not sure about rear) brake duct fins for 2019. Do these fins manage the top half of tyre wake in conjunction with the fins and bargeboards higher up on the side-pods, in a move to prevent interaction with the rear wing?
I'll try to rectify that... no idea what happened.