Restomod

Red Bull Technology and Singer Design

There are restomods, and then there are Singer restomods—the kind that make you wonder whether Stuttgart’s original engineers would smile, cry, or quietly take notes. Now Singer Vehicle Design has taken its obsessive reimagining of the Porsche 964 to a new level by teaming up with Red Bull Advanced Technologies, the engineering skunkworks behind Formula 1–grade simulations and structural wizardry.

Yes, that Red Bull.

The goal? Fix the one thing vintage 911s have never been great at: rigidity—especially when the roof goes missing.

Singer’s customers are the sort of people who know exactly how a car should feel at 140 mph through a fast sweeper, and they aren’t shy about asking for more. “Our clients are some of the most demanding drivers in the world,” says Mazen Fawaz, Singer’s head of strategy. “To achieve the standards they expect, we only work with the best.”

So Singer called in the people who build race cars that survive 300-kph curbs.

Step One: Tear It Down to the Bone

Every Singer restoration starts the same way: total annihilation.

The donor Porsche 964 is stripped of everything—body panels, interior, suspension, drivetrain—until only a bare steel monocoque remains. What’s left looks more like an archaeological artifact than a car. That naked shell is then cleaned, inspected, and prepped for what amounts to structural surgery.

This is where Red Bull Advanced Technologies enters the picture.

Using high-resolution 3D scanning and old-school hand measurements, RBAT digitally recreates the entire 964 chassis in a virtual environment. Every seam, every weld, every curve of 1990s Porsche steel is mapped. But the real magic comes next.

Formula 1 Math Meets a 1990s 911

RBAT feeds that digital 964 into Finite Element Analysis software—the same kind of simulation used to determine whether a Formula 1 monocoque will survive a 200-mph crash. The software twists, bends, and loads the Porsche chassis in thousands of virtual scenarios, identifying exactly which areas are weakest, especially in Cabriolets and Targas, which lack the structural help of a fixed roof.

Then the engineers start reinforcing.

RBAT designed 13 bespoke carbon-fiber structures that integrate into key load-bearing areas of the 964’s steel chassis. These aren’t bolt-on braces or aftermarket roll cages—they are carefully engineered, bonded and joined during the restoration so they become part of the car’s skeleton.

The result? A 175 percent increase in torsional stiffness.

That number is not a typo.

According to Singer and Red Bull, the reinforced open-top cars now match the rigidity of a coupe—something Porsche engineers in the early ’90s could only dream about.

Why Rigidity Matters

Chassis stiffness isn’t something you brag about at car meets, but it’s the secret sauce behind everything that makes a car feel right.

A stiff chassis means more precise steering, more consistent suspension behavior, better braking stability, and fewer squeaks, rattles, and shudders over rough pavement. It also means the car feels calmer and more refined at speed, even when it’s being driven hard.

In other words, it makes a 30-year-old 911 feel like a modern performance car—without losing its analog soul.

Built for Singer’s Brutal Turbo Cars

This Red Bull–engineered structure was developed specifically for Singer’s latest tribute to the legendary mid-1970s 930 Turbo. These aren’t gentle classics. They pack between 456 and 517 horsepower, send it all to the rear wheels through a six-speed manual transmission, and now sit on a chassis that’s finally strong enough to handle that kind of punishment.

That means fewer compromises, even in a Cabriolet or Targa. Roof off. Throttle pinned. No flex. No drama.

The Ultimate 964

What Singer and Red Bull have done here is more than just reinforce a classic Porsche. They’ve solved one of its fundamental flaws using tools developed for modern motorsport.

It’s a fusion of old-school air-cooled character and bleeding-edge structural engineering—a 911 that looks like 1990 but behaves like 2026.

And if you think that sounds expensive, you’re right. But for Singer’s clientele, perfection is the only acceptable option.

Source: Singer Vehicle Design

Tuning

Toyota Crystal Eye 60 Prius

For most of its life, the Toyota Prius has been the vehicular equivalent of beige carpet. Sensible, efficient, and about as emotionally charged as a toaster. But the current-generation Prius changed that narrative. It finally looks… good. Genuinely good. Toyota swapped the fridge-on-wheels silhouette for something sleek, low, and just edgy enough that you don’t feel like you need to apologize for driving it.

Naturally, that meant the tuners were going to get involved.

Enter the Crystal Eye 60 Prius, a one-off show car from Japan that answers a question nobody asked: What if the Prius were designed by a cyberpunk samurai with a Fast & Furious DVD collection?

The car debuted at the Tokyo Motor Show, where subtlety went to die. Built by lighting specialist Crystal Eye with help from Body Shop Kikuta, this Prius doesn’t just push the styling envelope—it shreds it into confetti and lights it on fire.

A Prius That Looks Ready to Commit Crimes

Up front, the car wears a splitter so large it could double as municipal snow-removal equipment. Above it sits a ventilated hood that suggests track-day intent, even if the powertrain underneath is still politely humming along in hybrid serenity. Wide, flat aluminum fender extensions flare outward, wrapping around 20-inch Work wheels that gleam like jewelry stolen from a supercar.

It’s the rear, though, where things really spiral into glorious madness.

A towering wing sprouts from the tailgate, flanked by angular fins that jut out like mechanical paddles. Beneath it all sits a massive rear diffuser, because nothing says “aerodynamic efficiency” like a Prius that looks like it’s about to enter a time-attack race.

And then there are the taillights: custom hexagonal LED units developed by Crystal Eye themselves. They’re sharp, futuristic, and will soon be sold to anyone who wants their own Prius—or anything else—to look like it belongs in a dystopian anime.

Laying Frame in a Hybrid

The entire thing rides on Air Rex Odin air suspension, allowing the Prius to drop to mere millimeters above the pavement when parked. It doesn’t just sit low—it lies in wait. It’s the kind of stance normally reserved for supercars and show queens, not for a plug-in hybrid whose natural habitat is the Whole Foods parking lot.

Yet here we are.

Still a Prius… Technically

Under all the carbon, aluminum, LEDs, and bosozoku-inspired chaos, the Crystal Eye 60 is still a Prius. It uses Toyota’s most powerful plug-in hybrid setup, good for 223 PS, which is respectable—but not exactly the stuff of street-racing legends. There are no turbochargers hiding beneath those vents, no engine swaps yet lurking in the shadows.

That makes this build all the more hilarious and brilliant. It looks like it should be illegal in at least three countries, yet it’s still technically road-legal in Japan.

Why It Exists

This Prius was never meant to be a production car. It’s a rolling billboard, built to showcase Crystal Eye’s lighting products and grab attention at auto shows. And it absolutely succeeds. In a sea of tastefully modified sports cars and hypercars, the most outrageous thing in the room is… a Prius.

Somehow, Toyota’s once-boring hybrid has become a blank canvas for wild creativity. And in the hands of Japan’s tuning culture, it has transformed into something that blurs the line between show car, anime villain, and rolling art installation.

If this is the future of the Prius, count us in—even if we’re still secretly laughing at it.

Source: Toyota

News

This Xiaomi SU7 Just Drove 265,000 Kilometers—and Its Battery Is Still On 94.5 Percent Capacity

If you want to understand the future of electric cars, sometimes it helps to look not at shiny auto-show concepts but at a very tired driver and a very not-tired battery.

Somewhere in China, a Xiaomi SU7 owner known online as Feng has quietly done what most EV skeptics insist can’t be done: he drove his electric sedan 265,000 kilometers in just 18 months—nearly the distance from Earth to the Moon—and the battery still looks like it just finished its break-in period.

According to a diagnostic report issued by Xiaomi’s own service center, the SU7’s 94.3-kWh pack is still holding 94.5 percent of its original capacity. In battery-speak, that’s astonishing. Feng averaged almost 500 kilometers per day, every day, for a year and a half. That’s the kind of usage that normally turns lithium-ion packs into cautionary tales. Instead, this one came back with barely a wrinkle.

To put that number in perspective, most automakers promise that after eight years or roughly 150,000 to 160,000 kilometers, your EV battery won’t degrade more than 20 to 30 percent. Tesla, for example, guarantees its Model 3 and Model Y will retain at least 70 percent capacity over that span. Feng’s SU7 has already blown past those mileage figures—and it’s still sitting north of 94 percent.

A High-Mileage Stress Test

The service report suggests the battery has gone through roughly 506 full charge cycles. That’s not light use. That’s the sort of cycling you’d expect to expose weaknesses in cell chemistry, thermal management, or charging strategy. Instead, the SU7’s pack seems to be taking it in stride.

And it’s not just the battery that’s holding up. Xiaomi’s technicians also noted that Feng hasn’t needed a brake-pad replacement yet, a reminder of how effective regenerative braking can be when used this heavily. Even the cooling system passed with flying colors—the coolant showed no water contamination, a detail that quietly signals good long-term system integrity.

In other words, this SU7 isn’t just surviving. It’s aging gracefully.

Why This Matters

Xiaomi may be new to the car business, but this kind of real-world data is exactly what separates marketing promises from engineering reality. Anyone can quote lab numbers. Feng delivered something far more valuable: a brutal, everyday stress test.

High-mileage EVs are still rare enough that every one of them becomes a rolling experiment. And this experiment suggests that Xiaomi’s battery management and thermal systems are doing something very right. If a pack can keep more than 94 percent of its capacity after 265,000 kilometers of near-constant driving, that’s not a fluke—that’s a design philosophy paying off.

The Road to 600,000

Feng isn’t done. His next target is 600,000 kilometers, which he expects to reach within three years. When he gets there, he plans to publish another full wear-and-tear report, effectively turning his SU7 into one of the world’s most documented long-term EV tests.

If the battery keeps degrading at this rate, that future report might be even more impressive than the first.

And for an industry still fighting doubts about durability, that may be the most important data point of all.

Source: Xiaomi; Photo: EPA-EFE

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