Red Bull doesn’t talk about its Formula 1 ‘factory’; instead, the Milton Keynes site is described as a ‘technology campus’. But that’s no pretentious exaggeration.
The expansion continues from what was originally a relatively humble base for Stewart Grand Prix in the late 1990s, with the new powertrain department the latest addition to the collection of Red Bull-branded buildings in the Tilbrook industrial estate.
It’s not finished yet, but it soon will be, creating an even greater premium for parking spaces as an extra 350-400 staff move into a site that’s already bursting at the seams.
It’s not all about F1 here, they tell us. Red Bull Advanced Technologies has widened the agenda, most famously with the Aston Martin Valkyrie hypercar project.
But tour the campus and it’s obvious that F1 is precisely what this place is all about. Just check out the cool conference room and its almost complete circle of Red Bull racers from the past 17 seasons. This is what drives this facility, the collection representing the reason why all these people turn up here every day: to help two racing drivers complete the next grand prix as quickly as they can.
That’s what makes the company’s latest diverting tributary all the more intriguing.
We won’t see the Red Bull RB17 hypercar until 2024 at the earliest, but it’s already percolating in the mind of the team’s design visionary, Adrian Newey, who will pull out as many tricks as he can from his F1 cars to create a track-day weapon he promises will offer “significantly more performance” than the already astounding Valkyrie.
There’s room for improvement, apparently. All those compromises and inhibiting road-car regulations ultimately frustrated a man who has spent his professional life trying to work around an ever-tightening F1 rulebook. Now, as Red Bull team principal Christian Horner puts it, he will be “unleashed”.
Should we care? In our grim reality and on face value, it’s hard to get too worked up by a car that can only be used on a track and will cost 50 people a vulgar £5 million each.