Sentences with phrase «turbine geometry»
"Turbine geometry" refers to the shape, size, and arrangement of the blades or vanes in a turbine. It impacts the efficiency and performance of the turbine by affecting the flow of fluid or gas through it. Full definition
For starters, it's a flat - as opposed to an inline - four, and gets variable turbine geometry in «S» guise.
autofocus.ca
The 2.0 - litre turbocharged diesel models have been radically redesigned, featuring variable turbine geometry and common - rail direct fuel injection.
The new diesel engine is exceptionally light thanks to its aluminium - alloy construction and offers innovative common - rail direct injection and a turbocharger with variable turbine geometry for optimum power and performance.
The powerplant sets standards in various areas such as its aluminium crankcase, its common - rail direct injection and turbocharger with variable turbine geometry which allow it to combine impressive punch with a further reduction in fuel consumption and emissions.
Porsche is still the only manufacturer to utilise turbochargers with variable turbine geometry in petrol engines.
The Boxster S borrows the 911 Turbo's Variable Turbine Geometry turbo technology, and it responds with an urgency to the throttle that makes the new 911 Carrera feel downright laggy.
Mazda says the new diesel unit has a remarkably low compression ratio of 14.8:1 and a bespoke variable turbine geometry turbocharger.
The Variable Twin Turbo for the first time features variable turbine geometry on the small turbocharger unit.
More notable is the engine's torque curve, which has been bolstered and broadened by the variable turbine geometry system.
Adjustment of turbine geometry is activated as a function of load conditions, via an electrical adjuster motor.
The 3.6 litre six - cylinder boxer engine boosted by two turbochargers with variable turbine geometry exclusive to Porsche in its combination with a gasoline engine drives the rear wheels via a six - speed manual gearbox.
Through adaptation of turbine flow characteristics to match the operating points, an exhaust - gas turbocharger with variable turbine geometry presents the opportunity to provide very high turbine output and thus high charge pressure from low engine speeds.
The Mercedes engineers brought about a noticeable improvement in the turbocharger's bottom - end response by incorporating newly developed turbine geometry and a cylinder - flushing process.
A shorter intake path and variable turbine geometry reduces turbo lag, and the diesel comes with an Incorrect Fuel Filling Prevention System.
New technological components include the improved turbocharger with variable turbine geometry integrated into the exhaust manifold.
Both the 2.0 - liter in the Boxster and the 2.5 in the S share parts and engineering / technology with the new turbo flat - six engines found in the 911 range, with the S employing 911 Turbo - derived variable turbine geometry for better throttle response at low and high revs.
This is an all new engine, and also uses BMW's TwinPower Turbo technology, or basically variable turbine geometry which allows the engine to put out slightly higher power (about 7 - 8 bhp more), but still reduces consumption (and emissions) by 17 % according to manufacturer data.
Porsche is still the only manufacturer to use turbochargers with variable turbine geometry in gasoline engines.
The 3.6 liter six - cylinder boxer engine features two variable turbine geometry turbochargers and provides power to the rear wheels exclusively through a six - speed manual gearbox.
Claimed to be a world first is the new variable turbine geometry on the small petrol that, Volkswagen claims, allows the compressor to deliver high charge pressure from low engine speeds allowing maximum torque to occur 35 per cent lower in the engine range.
Much of the 911 Turbo's improved performance can be attributed to the variable turbine geometry system, the first such system available on a turbocharged gasoline engine.
The larger engine is said to feature Porsche's Variable Turbine Geometry turbo tech from the 911 Turbo, and is estimated to provide 355 hp and 400 Nm.
The car is powered by a four - cylinder turbodiesel engine with common - rail injection and variable turbine geometry which produces 112 hp and a maximum torque of 270 Nm at 1,750 — 2250 rpm
Porsche is the only automaker using two turbos with variable turbine geometry in a gasoline engine, and the newest Turbo S uses different engine hardware for the first time — in this case, larger turbo impellers and a modified housing, enabling a higher 7,200 rpm redline.
The higher - powered S model uses variable turbine geometry, a technology that has filtered down from the 911 Turbo.
The new 718 Cayman S come equipped with variable turbine geometry (VTG).
This engine — like the engine in the 911 Turbo — also comes equipped with variable turbine geometry (VTG).
Porsche has confirmed some information on its 2007 911 Turbo: The sixth generation of this 911 model features a 480 - horsepower, twin - turbocharged, 3.6 - liter boxer engine with variable - turbine geometry, a redesigned all - wheel - drive system and freshened styling.
BMW's well - known 2.0 - liter unit features turbocharging with variable turbine geometry and Common Rail direct injection, delivering 190 metric horsepower at 4,000 rpm and 400 Nm (295 lb - ft) of torque between 1,750 and 2,500 rpm.
This eighth - generation Turbo includes two Variable Turbine Geometry (VTG) turbochargers, a three point eight liter, six - cylinder engine, an automated dual - clutch gearbox, and a wider body.
Two exhaust turbochargers with variable turbine geometry (VTG) make for a dynamic response, high torque and exceptional performance figures.
The Porsche 718 Cayman S gets an additional 0.5 - litre displacement advantage, with 257kW and peak torque of 420Nm between 1950 - 4500rpm thanks to the turbocharger equipped with Variable Turbine Geometry.
The power unit of the new 911 GT2 is based on the six - cylinder boxer engine of the 911 Turbo, with air supply by two exhaust gas turbochargers featuring variable turbine geometry (VTG).
The 718 Boxster S and 718 Cayman S come equipped with variable turbine geometry (VTG).
This engine — like the unit in the 911 Turbo — also comes equipped with variable turbine geometry (VTG).
The Twin Power for diesels designate the combination of third generation Common Rail direct injection system with variable turbine geometry.
The bigger engine uses a turbocharger with variable turbine geometry.
The six - cylinder boxer engine is boosted by two turbochargers with variable turbine geometry (exclusive to Porsche in its combination with a petrol engine) and drives the rear wheels via a six - speed manual gearbox.
A turbocharger with variable turbine geometry and common - rail direct injection allows the diesel powerplants driving the MINI Cooper SD Paceman and MINI Cooper D Paceman to offer both instantaneous pulling power and exceptionally low fuel consumption.
Porsche also uses a turbocharger with variable turbine geometry (VTG) for the S, an engineering detail shared with the 911 Turbo.
The S model turbocharger utilizes Variable Turbine Geometry (VTG) technology.
The new 118d is now even more responsive and economical; thanks to innovations such as reduced engine friction, thermodynamically optimised turbochargers with variable turbine geometry, and next - generation common - rail direct injection with magnetic - valve injectors.
Porsche continues to be the only carmaker to offer two turbochargers with variable turbine geometry for a petrol engine.
With 4 valves per cylinder and a variable turbine geometry the common - rail direct injection system of the new small diesel engine operates at a maximum injection pressure of 1600 bar.
The modern, long - stroke engine with the internal code 4P10 features two robust chain - driven overhead camshafts; four valves per cylinder; an exhaust gas turbocharger with variable turbine geometry; common rail injection system; and piezo injectors for precise metering of fuel.
These include aluminium crankcases, reduced engine friction, thermodynamically optimized turbochargers and variable turbine geometry, next - generation common - rail direct injection and magnetic - valve injectors.