Although there are suggestions that the changes are aimed particularly at slowing Red Bull Racing down, Allison said on Tuesday that it will affect all teams.
"The FIA's note will cause all teams, whether or not they use a blown floor, to change their operation," said Allison.
"The headline changes for the Silverstone GP are as follows: when the driver lifts his foot fully off the throttle pedal, then the ECU maps must be set up so that the engine [to all intents and purposes] closes the throttle - previously it was possible to configure the engine maps to leave the throttle open and reduce the engine power by other means.
"Furthermore, when the driver lifts fully off the throttle, the ECU maps must be configured to cut off the fuel supply to the engine β this is intended to prevent so called 'hot blowing' where the energy of the exhaust gas is increased by combustion."
Allison, whose team pioneered the radical forward-exit exhausts this year, conceded it was difficult to know how the changes will affect the performance of its car.
"It is not easy to judge the effect of this change on our competitiveness. The loss for each blown floor car will come from two separate effects β how much downforce will you lose and, in addition, how much will the loss of this downforce upset the balance of the car.
"All blown floor cars will lose downforce under braking as a result of these new restrictions. Some teams will lose more and some teams less; it is hard to know exactly what relative loss LRGP will suffer.
"However, it is possible that we will suffer less on the balance shift side of the equation because our forward exit exhausts produce their effect quite near the middle of the car. This means that as the exhaust blow waxes and wanes, it does not really disturb the aero balance of the car too much.
"With a rearward blower, the downforce from the exhaust is all generated at the rear axle. As the new rules reduce the blowing effect on corner entry much more than corner exit, it is possible that the rearward blowers will tend to suffer more nervousness under braking and more understeer on exit as a result of the new restrictions. We will find out in Silverstone."
He also made it clear his team is against changing the rules during the season.
"We would have preferred the status quo to remain for the rest of the season," Allison added.
Presumably because the car would have to be set up with more rear grip to offset the lack of downforce on corner entry, compared to the current off-throttle blown-diffuser. Of course, when on-throttle, the car would generate more rear downforce and naturally make it want to understeer. You could minimize that with shock settings, but you'd be fighting against a distinct difference in aero balance.hardingfv32 wrote:"more understeer on exit as a result of the new restrictions."
Why?
Brian
And yes, "when the driver lifts fully off the throttle, the ECU maps must be configured to cut off the fuel supply" should work, but never used 
Shelly i was responding to this, not your other posts.shelly wrote:@ringo: it is not haer say against evidence. But if you do not want to discuss because you can not put on the table something more solid than "it's in the images", then ok.
You have not recognized a F1 areodynamicist (SLC) even when he posted on this forum, so probably even if you get to chat with another one, you will question their opinion if it forces you to rethink your approach.
@expensive: biggest role in deflection is played by the flow on the side of the car, travelling at a little higher sped than he car's.
Then there is low pressure under the floor, and even lower pressure in the kink line region.
The car does not "suck" air from the sides. Look on any picture of an F1 car in the rain.shelly wrote:I think that exhaust gases follow aa bow trayectory, and enter the floor by the sides before the kink line, increasing downforce. This effect aadds to increased front suction peak.
Do gases go 100% under the floor? Do they partially/totally go outwards, on rear wheels or wider?
As I wrote before, wa can not conclude on exhaust trajectory using PC CFD (or worse EFD).
ringo, you must not mix the two things up: the effect on front suction peak is obvious/evident, the rearward trajectory is difficult to predict.
There is nothing "falling into place". What do you think is a wrong assumption on my side? And what do you think is hearsay?
About sucking air form the sides:
- if you suck it in before the kink line, you will get more mass flow rate, an increased suction peak on the line, thus increased downforce
-if you suck it in in the diffuser from the footplate, you can get some downforce from the vortex on the footplate edge
Yes there is a lot to it
