He didn't, he came in the lap after and swapped to hards.DiogoBrand wrote: ↑28 May 2019, 21:31Wow, I'm impressed that he did almost an entire race with that.
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He didn't, he came in the lap after and swapped to hards.DiogoBrand wrote: ↑28 May 2019, 21:31Wow, I'm impressed that he did almost an entire race with that.
Oh right, I didn't remember that.djones wrote: ↑28 May 2019, 21:36He didn't, he came in the lap after and swapped to hards.DiogoBrand wrote: ↑28 May 2019, 21:31Wow, I'm impressed that he did almost an entire race with that.
I can’t see how this makes a weight distribution change.zibby43 wrote: ↑29 May 2019, 05:35Tech Tuesday (addresses Merc's front suspension):
https://www.formula1.com/en/latest/arti ... 3ZraL.html
"The latest front suspension geometries cleverly oblige the car’s nose to dive relative to the suspension when a lot of steering lock is used. This induces not only a weight distribution change towards the front that helps the tyre build up load more quickly, but also induces more ground effect from the front wing and nose underside."
- "As you can see from the video at the top of the page, the more steering lock is applied, the angle of the suspension arm relative to the rest of the suspension changes, effectively levering the front of the car down."
"It is believed that Ferrari introduced the feature last year, quickly followed by Red Bull. Mercedes incorporated it into the design of this year’s W10 and it’s now being used by most of the other teams too."
"It’s particularly ingenious in that it allows a solution to low-speed understeer without compromising rear stability in high-speed corners."
Isn't it that the CoG moves because of inertia in the car?henry wrote: ↑29 May 2019, 09:53I can’t see how this makes a weight distribution change.zibby43 wrote: ↑29 May 2019, 05:35Tech Tuesday (addresses Merc's front suspension):
https://www.formula1.com/en/latest/arti ... 3ZraL.html
"The latest front suspension geometries cleverly oblige the car’s nose to dive relative to the suspension when a lot of steering lock is used. This induces not only a weight distribution change towards the front that helps the tyre build up load more quickly, but also induces more ground effect from the front wing and nose underside."
- "As you can see from the video at the top of the page, the more steering lock is applied, the angle of the suspension arm relative to the rest of the suspension changes, effectively levering the front of the car down."
"It is believed that Ferrari introduced the feature last year, quickly followed by Red Bull. Mercedes incorporated it into the design of this year’s W10 and it’s now being used by most of the other teams too."
"It’s particularly ingenious in that it allows a solution to low-speed understeer without compromising rear stability in high-speed corners."
I would think there are some transient forces with energy supplied by the power steering mechanism and the change in height of the COG but this is not weight change. The weight distribution can only be moved by moving the COG.
I believe the reason this is important is that a weight distribution change would apply through the corner but the transient forces only happen at turn in.
Inertial effects change the force distribution due to forces applied to the car. For inertial force to be transferred from the rear to the front of the car would need to be decelerated. I don’t see how the steering mechanism does that.SiLo wrote: ↑29 May 2019, 12:22Isn't it that the CoG moves because of inertia in the car?henry wrote: ↑29 May 2019, 09:53I can’t see how this makes a weight distribution change.zibby43 wrote: ↑29 May 2019, 05:35Tech Tuesday (addresses Merc's front suspension):
https://www.formula1.com/en/latest/arti ... 3ZraL.html
"The latest front suspension geometries cleverly oblige the car’s nose to dive relative to the suspension when a lot of steering lock is used. This induces not only a weight distribution change towards the front that helps the tyre build up load more quickly, but also induces more ground effect from the front wing and nose underside."
- "As you can see from the video at the top of the page, the more steering lock is applied, the angle of the suspension arm relative to the rest of the suspension changes, effectively levering the front of the car down."
"It is believed that Ferrari introduced the feature last year, quickly followed by Red Bull. Mercedes incorporated it into the design of this year’s W10 and it’s now being used by most of the other teams too."
"It’s particularly ingenious in that it allows a solution to low-speed understeer without compromising rear stability in high-speed corners."
I would think there are some transient forces with energy supplied by the power steering mechanism and the change in height of the COG but this is not weight change. The weight distribution can only be moved by moving the COG.
I believe the reason this is important is that a weight distribution change would apply through the corner but the transient forces only happen at turn in.
Here is what Whiting told in 2017:
We will therefore be asking you to provide us with all relevant documentation showing what effect steering has on the front ride height of your car and, in order to satisfy us that any effect is incidental, we believe that ride height should change by no more than 5.0mm when the steering wheel is moved from lock-to-lock.
Whilst some change is inevitable when the steering wheel is moved from lock-to-lock, we suspect that the effect of some systems was a far from incidental change of ride height.
We also believe that any non-incidental change of ride height is very likely to affect the aerodynamic performance of the car.
There's what he said and what is actually in the technical directive. The AMUS article quoted earlier states that it is measured at 12 degrees (with a diagram)LM10 wrote: ↑29 May 2019, 16:00Here is what Whiting told in 2017:
We will therefore be asking you to provide us with all relevant documentation showing what effect steering has on the front ride height of your car and, in order to satisfy us that any effect is incidental, we believe that ride height should change by no more than 5.0mm when the steering wheel is moved from lock-to-lock.
Whilst some change is inevitable when the steering wheel is moved from lock-to-lock, we suspect that the effect of some systems was a far from incidental change of ride height.
We also believe that any non-incidental change of ride height is very likely to affect the aerodynamic performance of the car.
The AMuS article didn't quote anything. They just claimed that those figures (5 mm ride height change at 12 degree steering angle) were in the technical directives. I've looked into the regulations and searched for it, but couldn't find any numbers as to how the steering angle should influence the ride height. The only thing we have are the words of Charlie Whiting from 2017, but as long as they are not written down in the regulations, they are not of significance.richardn wrote: ↑29 May 2019, 16:35There's what he said and what is actually in the technical directive. The AMUS article quoted earlier states that it is measured at 12 degrees (with a diagram)LM10 wrote: ↑29 May 2019, 16:00Here is what Whiting told in 2017:
We will therefore be asking you to provide us with all relevant documentation showing what effect steering has on the front ride height of your car and, in order to satisfy us that any effect is incidental, we believe that ride height should change by no more than 5.0mm when the steering wheel is moved from lock-to-lock.
Whilst some change is inevitable when the steering wheel is moved from lock-to-lock, we suspect that the effect of some systems was a far from incidental change of ride height.
We also believe that any non-incidental change of ride height is very likely to affect the aerodynamic performance of the car.
Remember that Monaco is very much an outlier and the 20 degree of steering lock used at the hairpin is much more than at any other circuit. 12 degrees is more steering angle than needed at most other circuits to follow the racing line.
But as I already told, Mercedes still uses this system, so maybe the amount of suspension movement we've seen in Monaco doesn't significantly move the front of the car down to gain aerodynamic performance. If so, I'm still interested in the answer of my initial question - which other benefits would such a suspension movement, without changing the ride height, have?With the exception of the parts necessary for the adjustment described in Article 3.6.8, any car
system, device or procedure which uses driver movement as a means of altering the
aerodynamic characteristics of the car is prohibited.
"TD -044", just find itLM10 wrote: ↑29 May 2019, 17:22The AMuS article didn't quote anything. They just claimed that those figures (5 mm ride height change at 12 degree steering angle) were in the technical directives. I've looked into the regulations and searched for it, but couldn't find any numbers as to how the steering angle should influence the ride height. The only thing we have are the words of Charlie Whiting from 2017, but as long as they are not written down in the regulations, they are not of significance.richardn wrote: ↑29 May 2019, 16:35There's what he said and what is actually in the technical directive. The AMUS article quoted earlier states that it is measured at 12 degrees (with a diagram)
Remember that Monaco is very much an outlier and the 20 degree of steering lock used at the hairpin is much more than at any other circuit. 12 degrees is more steering angle than needed at most other circuits to follow the racing line.
So, with the current information we have, it can be told that if the ride height of the Mercedes changed as much as the suspension movement indicates, it would not seem to comply with article 3.8, which says:But as I already told, Mercedes still uses this system, so maybe the amount of suspension movement we've seen in Monaco doesn't significantly move the front of the car down to gain aerodynamic performance. If so, I'm still interested in the answer of my initial question - which other benefits would such a suspension movement, without changing the ride height, have?With the exception of the parts necessary for the adjustment described in Article 3.6.8, any car
system, device or procedure which uses driver movement as a means of altering the
aerodynamic characteristics of the car is prohibited.
