'12 Ferrari 458 Italia, 1,600 Miles, One Owner on 2040-cars

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Ryan Tuerck's Ferrari-powered Scion drifts, crashes, fixes, and drifts again

We were pretty astonished when Ryan Tuerck and Gumout shoved a Ferrari 458 V8 into a Scion FR-S. And as awesome as that fact alone may be, it's even more amazing that it's a fully functional drifter, not just a show car. Tuerck recently took it out to Portland, Ore. to do some sweet drifting on a mountain road. Unfortunately for him and the car, he did something substantially less sweet right off the bat. As you'll see in the video, in just the second corner of the course, Tuerck drives the front corner of the GT4586 right into the dirt cliff on the side of the road. For a moment, it looks like things are all right, but the car starts pulling to the right and he stops the car for repairs. After fixing bits including a thoroughly bent tie-rod, the GT4586 is good as new. We're glad the car wasn't down for long, because the drifting show following the repairs was fantastic. In the video, Tuerck throws the Scion into high-speed, super smoky drifts. And all of it happens to the tune of a shrieking Ferrari V8. It's well worth a few minutes of your time to watch. Related Video: Image Credit: YouTube / Donut Media Ferrari Scion Coupe Racing Vehicles Videos toyota gt86 toyota 86

Ferrari launches 2014 Formula One engine, tests it in a LaFerrari? [w/videos]

Ferrari is the last of the three engine manufacturers remaining in Formula One to reveal its 2014 power unit. Called the 059/3, like the Mercedes and Renault units it is a turbocharged, 1.6-liter V6 further boosted by an energy recovery system that is twice as powerful as before. The 2013 KERS was good for 80 horsepower, could power the car for six seconds and reduce a lap time by about 0.3 seconds. For 2014, the energy recovery system puts out 160 hp, powers the car for 30 seconds on full batteries and, according to Ferrari, can shave a massive three seconds per lap.
The car that surrounds this engine doesn't have a name yet - that will be chosen by Ferrari's social media followers in January from a selection of names provided by the Scuderia.
Ferrari didn't provide an audio sample of the power unit at its introduction, but a brief video taken at Fiorano has led folks to believe that the team has been testing the engine in a revised LaFerrari chassis. The clip shows a camouflaged version of the marque's new supercar fitted with a roof intake and sounding nothing at all like a V12 as it takes the hairpin and powers onto the straight.

Ferrari patents a fancy and fascinating electric turbocharger

While turbocharging has improved vastly over the years, and it has enabled cars to become both more powerful and more efficient, there's always room for improvement. Turbochargers scavenge exhaust gas pressure and use it to turn a compressor that forces intake air into the cylinders. However, as the patent points out, this means the intake compressor and the exhaust turbine are physically coupled, and have to spin at the same rate. Ferrari's design divorces the two, and it's a happy breakup. The key is hooking up the two components of the turbo to their own individual electric motors, with an energy storage device in between. It's different than the electric supercharger systems you have seen on certain Audi products, for example. Those systems recover energy like a hybrid, store it, and then use it to drive an intake compressor. It supplements conventional turbochargers that harvest energy from the exhaust. In systems like Audi's, the electric supercharger is supplementing the sequential conventional turbochargers when they're not operating efficiently, at very low RPM in particular. It works well, but it's complicated, and it is a workaround for the limitations of a conventional turbocharger. See below for an animation of the Audi system. This content is hosted by a third party. To view it, please update your privacy preferences. Manage Settings. Usually, optimizing a turbo is a compromise between figuring out what RPM is ideal for each side to spin at to generate power. A smaller compressor generates boost more quickly, but loses efficiency at higher RPM. But there's way more energy in high-RPM exhaust gasses. By hooking up the turbine to an electric motor instead, you can harvest energy from the exhaust throughout the rev range, and particularly when the engine is pushing lots of gasses through. And you can store that energy in a battery if it's not needed at that moment. The intake-side compressor also has a reversible electric motor attached. It is not physically connected to the turbine, so it can operate at any time the computers decide it's beneficial. As engine RPM increases, the compressor doesn't have to increase its speed beyond its optimal range, so there's less energy wasted. And at low RPM situations, when a conventional turbocharger wouldn't have enough exhaust gas passing through its turbine side to generate useful boost in the compressor side, the electric motor can spin up Ferrari's divorced compressor to provide some boost.