Aero chronicle of Arctic Rally Finland 2021

This post is dedicated to the memory of the great Hannu Mikkola. RIP

The first edition of the Arctic Rally Finland represented not only a great event with very spectacular images but also a technical challenge for all teams, due to the specific conditions. We reviewed the impact of low temperatures and ice build-up on the car’s performance before the event. Now, once completed, some technical details are worth reviewing.

Despite the ambient temperature was above expectation during the event, some specific solutions could be seen, such as the different blocking plates in the front grills. The image below shows not only the front grill protection that reduces the air entering into the engine bay but also the reduced size of the bonnet vents used by Toyota (as less air has to be removed) while preventing snow to enter the engine bay in the event of the car colliding head-on with a snowbank.

E.Evans/S.Martin, Toyota Yaris WRC, Arctic Rally Finland 2021, 5th – picture by McKlein / Toyota Gazoo Racing WRT

The image also shows (same as in the picture below) how some ice was accumulated on the lower dive planes of the Toyota Yaris WRC, increasing the roughness of the surface and leading to some more drag.

S.Ogier/J.Ingrassia, Toyota Yaris WRC, Arctic Rally Finland 2021, 20th – picture by McKlein / Toyota Gazoo Racing WRT

Another solution for the low ambient temperatures was the blocking of rear brake and transmission air intakes, in order to avoid excessive cooling causing poorer performance of these elements. The image below shows how Toyota and Hyundai blocked these intakes during the event.

Toyota Yaris WRC (top) and Hyundai i20 Coupé WRC at Arctic Rally Finland 2021 – pictures extracted from wrcplus.com

The presence of snow in all stages forced the teams to block the rear fender vents, in order to prevent snow accumulation that would cause extra weight and made them ineffective in their main function: removing the air from the wheel space, thus releasing pressure. Teams and drivers opted for different blocking strategies: from total blockages, such as Bertelli/Scattolin to different degrees of blockage in the Yaris and the Fiesta and no blockage in the Hyundai.

From left to right: Bertelli/Scattolin Ford Fiesta WRC, Rovanperä/Halttunen Toyota Yaris WRC, Evans/Martin Toyota Yaris WRC, Suninen/Markkula Ford Fiesta WRC and Breen/Nagle Hyundai i20 Coupé WRC at Arctic Rally Finland 2021

The result was that still snow was accumulated in the rear fender vents, no matter the strategy used. The image below shows how the Yaris WRC of Rovanperä/Halttunen and Evans/Martin ended up full of snow, even though the different blocking strategy.

Rovanperä/Halttunen Toyota Yaris WRC (left) and Evans/Martin Toyota Yaris WRC (right) at Arctic Rally Finland 2021 – images extracted from wrcplus.com (Mads cam)

In the case of the Hyundai, the cars run most of the time without rear fender vents. The central part, containing the big vertical strakes easily detached from the car when hitting the snowbanks, leaving a big hole in the center of the rear fender, such as shown in the left image below. The lower vent also was often lost, because of the snowbank use, leaving the Alzenau cars with no fender vents.

C.Breen/P.Nagle, Hyundai i20 Coupé WRC, Arctic Rally Finland 2021, 4th – images extracted from wrcplus.com (Mads cam)

The result was that they hardly accumulated snow in the rear of the car. But they also lost the advantage of the rear fender vents. The image below shows how this part works (when available).

T.Neuville/M.Wydaeghe, Hyundai i20 Coupé WRC, Arctic Rally Finland 2021, 3rd – picture by Austral / Hyundai Motorsport GmbH

The air (and snow) from the wheel space is sent to the sides of the car, thus avoiding its interaction with the car wake. The car wake is an important source of drag. The loss of the rear fender vents resulted in more air sent to the car wake, thus increasing the drag and limiting their top speed. Casually or not, the Hyundai seemed to be the car with a lower top speed during the event, and this is possibly one of the reasons.

T.Neuville/M.Wydaeghe, Hyundai i20 Coupé WRC, Arctic Rally Finland 2021, 3rd – image extracted from wrcplus.com (Mads cam)

C.Breen/P.Nagle, Hyundai i20 Coupé WRC, Arctic Rally Finland 2021, 4th – picture by Fabien Dufour / Hyundai Motorsport GmbH

The high speed and the impacts with the snowbanks represented a tough test for most of the aero parts, not only for the rear fenders. The reliability of rear diffusers and dive planes suffered from these conditions, at the price of losing them or suffering serious damages, as shown in the pictures above.

G.Greensmith/E.Edmondson, Ford Fiesta WRC, Arctic Rally Finland 2021, 10th – picture by Henri Vuorinen Photography

The Arctic event included some very fast stages: the average speed was over 130 km/h in six out of 10 stages. Three of them have entered the top 10 of the fastest stages run by the 2017 WRC car generation, as shown in the table below. Note that, for the first time, a non-Toyota car enters the top ten, thanks to the stage win by the Hyundai i20 Coupé WRC driven of Tänak/Järveoja at Siikakämä.

So high speeds confirm the importance of the aerodynamics in the event, and the penalty caused by the loss of any of the aero parts.

Toyota won four out of the six super-fast stages (66,6%), while Hyundai the other two (33,3%). It might seem a poor result, but it is not. It confirms the progress of the Hyundai i20 Coupé WRC at high speed, as the percentage before this event, on the super-fast stages (average speed above 130 km/h) was 80% of the stages were won by Toyota, only 12% by Hyundai and 8% by M-Sport/Ford.

O.Tänak/M.Järveoja, Hyundai i20 Coupé WRC, Arctic Rally Finland 2021, 1st – picture by Fabien Dufour / Hyundai Motorsport GmbH

During the Arctic Rally Finland 2021 very sad news arrived about one of the greatest rally drivers ever, he had left us. Hannu Mikkola, Rally World Champion in 1983. Requiescat in pace, Hannu.

H.Mikkola/A.Hertz, Audi Quattro, Rally Portugal 1983, 1st

 

8 thoughts on “Aero chronicle of Arctic Rally Finland 2021

    • 2021-03-01 at 16:46
      Permalink

      Thanks, glad that you like it!

      Reply
  • 2021-03-01 at 17:34
    Permalink

    Muy buena la explicación. Gran pedagogo.

    Reply
    • 2021-03-01 at 18:04
      Permalink

      Es que nuestros lectores son de gran altura, nos lo ponen muy fácil. Y son muy agradecidos. Mil gracias, company!

      Reply
  • 2021-03-01 at 20:27
    Permalink

    As always a very nice and clear article ! 👏👏👏 You have the rare gift to make simple complex arguments. Thanks, from Italy.
    Antonio

    Reply
    • 2021-03-01 at 21:30
      Permalink

      Grazie tanti, Antonio! Sono molto contento che ti piaccia, è un piacere per me.
      Lluis

      Reply
  • 2021-03-02 at 10:38
    Permalink

    Hello again, nice way to start a day, reading your article 🙂

    There has not been too much talk about the transmission cooling. I understand that differentials have some sort of cooling, but the gearbox as well ? And as I have seen from some pictures, differentials were cooled by some device with liquid cooling. Are the transmissions cooled just by liquid or also with air and if so, then is the air directed to its destination from the brake cooling ducts, as you also mentioned that briefly in this article ?

    Hyundai suffered by the loss of rear fenders. How did it affect the car wake behind the car ? Also, how much does losing rear fenders affect drag and downforce in different conditions, for example would the effect maybe be bigger in winter or summer. (like air temperature, density, humidity, air speed etc.)

    Reply
    • 2021-03-02 at 21:38
      Permalink

      Hello Laur, great to have your interesting questions.
      Transmission cooling is a subject I expect to cover soon. As far as I know, it is air-cooled. The Fiesta WRC is the only car with a duct for cooling transmission, while the Yaris and the i20 not, they use un-forced air from under the car.
      The loss of the rear fender allows air to flow towards the car’s wake with no restriction, making the wake bigger and more draggy. The effect will be worse when the ambient conditions make the air denser, such as very low temperature, very low altitude and very low humidity content.

      Reply

Leave a Reply to llluis555 Cancel reply

Your email address will not be published. Required fields are marked *