Volkswagen has high hopes for its all-electric I.D. R hillclimb race car. With plans to hit the Pike’s Peak International Hill Climb later this year, VW hopes a win at that prestigious event with an EV will help environmentally-conscious consumers to look beyond the highly public “dieselgate” emissions scandal from 2015. To make sure everything goes to plan, the company is breaking new ground in aerodynamic efficiency with its track-ready racer.
That efficiency will be critical, because there’s a lot less air to work with at Pike’s Peak than most place. “The start line is located at an altitude just above 9,000 feet, with the finish at 14,115 feet above sea level. The low air pressure up there means that the aerodynamic conditions are different to those at a racetrack on flat land,” explains François-Xavier Demaison, Technical Director at Volkswagen Motorsport and the man responsible for developing the I.D. R Pikes Peak as project manager.
You can read more about how VW is approaching the aero challenge of Pike’s Peak in the company’s official press release, below. Then, let us know what you think of VW chances this summer in the comments section at the bottom of the page.
VOLKSWAGEN I.D. R PIKES PEAK BREAKS NEW GROUND IN AERODYNAMICS
Wolfsburg – In preparation for the Pikes Peak International Hill Climb 2018, the Volkswagen Motorsport team engineered the aerodynamics of the I.D. R Pikes Peak—the brand’s first fully-electric racing car—specifically to tackle the most famous hill climb in the world. The goal at the race, which takes place on June 24th in Colorado Springs, CO, is to break the record in the class for electric prototypes, which currently stands at 8:57.118 minutes.
“The start line is located at an altitude just above 9,000 feet, with the finish at 14,115 feet above sea level. The low air pressure up there means that the aerodynamic conditions are different to those at a racetrack on flat land,” explains François-Xavier Demaison, Technical Director at Volkswagen Motorsport and the man responsible for developing the I.D. R Pikes Peak as project manager. Unlike other racing disciplines though, the Pikes Peak race features relatively open regulations, giving the engineers far more leeway to design the chassis and rear wing of the racecar.
During the winding 12.4-mile drive to the summit of Pikes Peak, a top speed of around 155 mph is reached—relatively low for a prototype like the I.D. R, as it could theoretically go far faster. “For this reason, we concentrated mainly on achieving optimal cornering speeds. The entire chassis is designed to generate as much downforce as possible, without causing too much aerodynamic drag,” says Demaison.
The most visually striking result of this strategy is the oversized rear wing on the I.D. R Pikes Peak. “The altitude on Pikes Peak means that the air we are driving through is on average 35 percent thinner. As a result, we lose 35 percent of our downforce compared to a racetrack at sea level. The huge rear wing allows us to compensate for some of this lost downforce,” explains Willy Rampf, technical consultant to the project with years of Formula 1 experience. “The imaginative aerodynamic development means that we will still achieve maximum downforce greater than the weight of the car during the hill climb.”
Volkswagen Motorsport used a half-scale model to test a host of different variants of the Pikes Peak racer in the wind tunnel. The final touches were then put to a full-size chassis on the rolling-road wind tunnel in the Porsche development center in Weissach. “It was greatly beneficial to be able to use resources from within the Group,” confirms Demaison.
New components were often produced in quick time on a 3D printer. “We printed about 2,000 parts. In doing so, we saved a lot of time,” says Dr. Hervé Dechipre, who, as a CFD engineer at Volkswagen Motorsport, is responsible for the aerodynamics on the I.D. R Pikes Peak.
With its two electric engines, which together generate 500 kW (671 horsepower), the I.D. R avoids the cooling issues that face combustion-engined vehicles. This made it possible to reduce the size of the intakes in the chassis, which are traditionally aerodynamic drawbacks. However, the thin air at altitude has a negative effect on the efficiency of the cooling.
Simulation software provided by technology partner ANSYS is used to calculate the ideal compromise. “We could not manage this solely with the data from the wind tunnel, where it is not possible to recreate the thin air,” says Demaison. “The simulation was a great help in determining the dimensions required for the cooling system.”
In the meantime, the findings from the development phase have been optimized in great detail in comprehensive tests. The first test run on the original route is planned for the end of May. Driver Romain Dumas and the Volkswagen Motorsport team then begin the final phase of their preparations leading up to race day.
Source | Images: Volkswagen.