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Max Taylor - Aerodynamics and Motorsport Engineering

2021 Williams F1 CFD

Posted byMax TaylorApril 21, 2021April 22, 2021Posted inAerodynamics

Thanks to some clever people I was able to get a CAD model of the
current 2021 Williams F1 car -- that's not something that happens
every day, so of course I had to run CFD on it.

[image-1]CAD Geometry

The suspension positions on the model were set up for around 2.08
degrees rake, so that's how I've run it for the baseline. To make it
easier on myself I've also replaced the wheels and tires with the
geometry from my MVRC car (see my previous post). The only
problematic geometry was the brake ducts which were in pretty bad
shape, so I went ahead and made some simplified parts to replace them
-- I especially wanted to capture the winglets on the rear duct:

[image-3]Simplified Brake Ducts

The other notable issue was that the diffuser did not have any
strakes. I may try to add some in later but for now I'm running
without them.

Here are the results:

CD    CL     L/D    CLF    CLR
1.746 -4.598 -2.634 -2.004 -2.594

Baseline Results, 2.08 deg rake. A = 1 m^2

CL      CL     CL Rear CD      CD    CD Rear CL/CD     CL/CD  CL/CD
Front   Body   Wing    Front   Body  Wing    Front     Body   Rear
Wing                   Wing                  Wing             Wing
-1.194  -2.379 -1.158  0.169   0.573 0.402   -7.065    -4.152 -2.881

Breakdown by Part

The drag looks to be rather high, but otherwise I think these numbers
are at least in the right ballpark, given the limitations of the CFD
setup (there are clearly areas where the mesh is limiting the
performance). For reference, when I tried to match my lapsim program
to telemetry from the 2020 Spanish GP, I arrived at CL = -5.421 and
CD = 1.150 (perhaps more about that in another post). Balance also
looks reasonable at 43.6% front, a few percent rearward of the dry
weight distribution (45.5% for 2021).

Naturally, these numbers change dramatically with ride height. I've
begun running a ride height map and I'll make a separate post about
that when all the runs are finished.

Below are a series of images, enjoy:

  * [1]Surface Velocity. Lots of flow going around the sidepod to the
    floor edge.
  * [4]Flow nicely attached over the sidepods and sweeping down
    towards the diffuser.
  * [2]Interesting flow split between center and outboard of the
    floor as it comes through the bargeboards.
  * [3]

  * [5]Surface pressure. Note the low pressure regions on top of the
    front suspension, halo, and sidepod winglets as the front wing
    upwash is re-directed down towards the rear of the car.
  * [6]Surface pressure.
  * [7]Lots of performance coming from the leading edge of the floor.
  * [8]Surface pressure.

  * [9]Vortices on the upper surface.
  * [10]Vorticies
  * [11]Good shot here of the cape's function. Rolling up a vortex
    which interacts with the bargeboards and ultimately travels the
    length of the floor.
  * [12]Also interesting to note the floor edge vortex which seems to
    pull a lot of high-energy flow into the diffuser.

  * [13]Velocity slice at the ground plane. Bargeboard working hard
    to push the front tire wake outboard.
  * [14]Velocity slice on the top side of the floor. Notice the high
    speed flow between the diffuser and rear tire.
  * [15]Diffuser throwing air outboard behind the rear tire.

  * [16]Centerline velocity slice
  * [17]Some separation on the front suspension arms, but lots of
    clean air headed to the rear wing.
  * [18]Further outboard the flow is better aligned with the
    suspension.
  * [19]Sloped sidepod directing flow down to the floor.

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Posted byMax TaylorApril 21, 2021April 22, 2021Posted inAerodynamics

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