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78-617: The Triumph V8 is a 3.0 litre V8 developed and built by the Triumph Motor Company for the Triumph Stag . The engine was a development of the Triumph slant-four engine . It consisted of a cast iron block and aluminium cylinder heads with a single overhead cam per bank. The Stag was developed between 1964 and 1969. Whilst originally seen as little more than a convertible version of the Triumph 2000 saloon , as development progressed

156-426: A longitudinal engine layout and rear-wheel drive (or all-wheel drive). However, V8 engines have also occasionally been used in transverse engine front-wheel drive vehicles, sometimes using closer cylinder bore spacings and narrower cylinder bank angles to reduce their space requirements. The classification of 'big-block' or 'small-block' refers to the engine's external dimensions and does not necessarily indicate

234-539: A 2.5 L (153 cu in) V8 engine. BMW's first V8 engine was the 1954–1965 BMW OHV V8 engine , a petrol engine with overhead valves and all-aluminum construction. The company resumed production of V8 engines in 1992 with the BMW M60 aluminum double overhead camshaft engine, and V8 engines have remained in production until today. BMW's first turbocharged V8 engine was the 1998–2009 M67 twin-turbocharged diesel engine. The first turbocharged V8 petrol engine from BMW

312-521: A 5.6 L (340 cu in) Chrysler LA engine and built on the chassis of a 1950s Chrysler Imperial. The 1934–1938 Tatra 77 rear-engined sedan was initially powered by 3.0 L (183 cu in) petrol V8, which was air-cooled and used an overhead camshaft that operated the valves using a 'walking beam' rocker arrangement. This model line continued until 1999 when the Tatra 700 ended production. Tatra also produced diesel V8 truck engines from

390-618: A 60-degree V-angle because it was based on a V6 engine with a 60-degree V-angle. Both the Ford and Volvo engines were used in transverse engine chassis, which were designed for a front-wheel-drive layout (with an on-demand all-wheel drive system in the case of the Volvos ). To reduce the vibrations caused by the unbalanced 60-degree V-angle, the Volvo engines used a balance shaft and offset split crankpins . The Rolls-Royce Meteorite tank engine also used

468-545: A 60-degree V-angle, since it was derived from the 60 degree V12 Rolls-Royce Meteor which in turn was based on the Rolls-Royce Merlin V12 engine . Other V-angles have been used occasionally. The Lancia Trikappa , Lancia Dilambda , and Lancia Astura , produced 1922–1939, used narrow angle V8 engines (based on the Lancia V4 engine ) with V-angles of 14–24 degrees. The 1932 Miller four-wheel drive racing cars used

546-419: A V-angle (the angle between the two banks of cylinders) of 90 degrees. This angle results in good engine balance , which results in low vibrations. However, the downside is the greater width of the engine compared to those that use a smaller V-angle. V8 engines with a 60-degree V-angle were used in the 1996–1999 Ford Taurus SHO , the 2005–2011 Volvo XC90 , and the 2006–2009 Volvo S80 . The Ford engine used

624-565: A V-angle of 90 degrees and was built in displacements of 4.1 L (253 cu in) and 5.0 L (308 cu in), the latter being de-stroked to 5.0 L (304 cu in) in 1985. The Holden V8 engine was used in various models, including the Kingswood, Monaro, Torana, Commodore, and Statesman. Versions tuned for higher performance were sold by Holden Dealer Team and Holden Special Vehicles , including versions stroked to up to 5.7 L (350 cu in). The Holden V8 engine

702-579: A V8 engine was the 1965 Chrysler Valiant (AP6) , which was available with an American-built 4.5 L (273 cu in) Chrysler engine. The first locally designed V8 Ford was the 1966 Ford Falcon (XR) and the first V8 Holden was the 1968 Holden HK , both using engines supplied by their parent companies in the United States. The first V8 engine to be mass-produced in Australia was the 1969–2000 Holden V8 engine . This cast-iron overhead valve engine used

780-460: A V8 engine was the 1988 Audi V8 luxury sedan. Its first model to use a V8 diesel engine was the D2 A8 3.3 TDI in 2000. The first V8-engined Alfa Romeo road car was the 1967–1969 Alfa Romeo 33 Stradale mid-engined sports car, of which 18 were produced. This was followed by the 1970–1977 Alfa Romeo Montreal front-engined sports car. The engines for both cars are based on the 90-degree V8 engine from

858-406: A V8 engine with a V-angle of 45 degrees. The 8-cylinder versions of the 1945 through 1966 EMD 567 diesel locomotive engine also used a V-angle of 45 degrees. Most V8 engines fitted to road cars use a cross-plane crankshaft since this configuration produces less vibration due to the perfect primary balance and secondary balance. The cross-plane crankshaft has the four crank pins (numbered from

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936-400: A common shaft. The first prototype was finished in 1915 with the aim of overcoming the power loss experienced by aircraft engines due to the decreased density of air at high altitudes. However, the prototype was not reliable and did not reach production. Another early patent for turbochargers was applied for in 1916 by French steam turbine inventor Auguste Rateau , for their intended use on

1014-425: A design by Scottish engineer Dugald Clerk . Then in 1885, Gottlieb Daimler patented the technique of using a gear-driven pump to force air into an internal combustion engine. The 1905 patent by Alfred Büchi , a Swiss engineer working at Sulzer is often considered the birth of the turbocharger. This patent was for a compound radial engine with an exhaust-driven axial flow turbine and compressor mounted on

1092-669: A direct competitor for the Rover 'P6' 3500 . Triumph also tried to sell the engine to the Morgan Motor Company but that company chose the Rover V8 as well. It is believed that Saab tested the V8 for the Saab 99 mainly for US markets but the oil crisis in 1973 finally caused cancellation of the project in favour of turbocharging , and no documents of the project nor any prototypes have survived. The result

1170-405: A limiting factor in the peak power produced by the engine. Various technologies, as described in the following sections, are often aimed at combining the benefits of both small turbines and large turbines. Large diesel engines often use a single-stage axial inflow turbine instead of a radial turbine. A twin-scroll turbocharger uses two separate exhaust gas inlets, to make use of the pulses in

1248-407: A mix of imported and local parts. A 4.4 L (269 cu in) version of the Rover V8 engine was produced in Australia for the ill-fated 1973–1975 Leyland P76 sedan. The engine had an overhead valve design and was the only all-aluminum engine made in Australia. The 1958–1965 Hongqi CA72 was a luxury car, of which approximately 200 were built for government officials. It was powered by

1326-566: A pioneering role with turbocharging engines as witnessed by Sulzer, Saurer and Brown, Boveri & Cie . Automobile manufacturers began research into turbocharged engines during the 1950s, however the problems of "turbo lag" and the bulky size of the turbocharger were not able to be solved at the time. The first turbocharged cars were the short-lived Chevrolet Corvair Monza and the Oldsmobile Jetfire , both introduced in 1962. Greater adoption of turbocharging in passenger cars began in

1404-473: A single overhead camshaft and was rear-mounted in the vehicles. The company's first V8 road car was the 1973–1974 Dino 308 GT4 mid-engined sports car. The engine is a 90-degree all-aluminum V8 with double overhead camshafts. In 1975, the 2.0 L (122 cu in) engine in the Ferrari 208 GT4 became the smallest production V8 engine ever produced. The model lineage of mid-engined V8 road cars continues to

1482-641: A strict ruleset to follow until the 1972 season, when engines were no longer allowed to be any bigger than 358 cu in (5.9 L) for the purpose of reducing speeds caused by the rapid aerodynamic advancements from 1969 to 1971. In the American Top Fuel class of drag racing, V8 engines displacing 500 cu in (8 L) today produce outputs of over 7,000 kW (10,000 hp). and 10,000 N⋅m (7,400 lb⋅ft). The engines used in Top Fuel and Funny car drag racing are typically based on

1560-530: A turbocharger is powered by the kinetic energy of the exhaust gases, whereas a supercharger is mechanically powered (usually by a belt from the engine's crankshaft). However, up until the mid-20th century, a turbocharger was called a "turbosupercharger" and was considered a type of supercharger. Prior to the invention of the turbocharger, forced induction was only possible using mechanically-powered superchargers . Use of superchargers began in 1878, when several supercharged two-stroke gas engines were built using

1638-409: Is considered to be the first V8 engine produced in significant quantities. The 1914 Cadillac L-head V8 engine is considered the first road-going V8 engine to be mass-produced in significant quantities, with 13,000 sold the first year. This engine was built in the United States and was greatly assisted by Cadillac's pioneering use of electric starter motors . The popularity of V8 engines in cars

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1716-412: Is done with the use of adjustable vanes located inside the turbine housing between the inlet and turbine, which affect flow of gases towards the turbine. Some variable-geometry turbochargers use a rotary electric actuator to open and close the vanes, while others use a pneumatic actuator . If the turbine's aspect ratio is too large, the turbo will fail to create boost at low speeds; if the aspect ratio

1794-470: Is increasing. The companies which manufacture the most turbochargers in Europe and the U.S. are Garrett Motion (formerly Honeywell), BorgWarner and Mitsubishi Turbocharger . Turbocharger failures and resultant high exhaust temperatures are among the causes of car fires. Failure of the seals will cause oil to leak into the cylinders causing blue-gray smoke. In diesel engines, this can cause an overspeed,

1872-402: Is that the optimum aspect ratio at low engine speeds is very different from that at high engine speeds. An electrically-assisted turbocharger combines a traditional exhaust-powered turbine with an electric motor, in order to reduce turbo lag. This differs from an electric supercharger , which solely uses an electric motor to power the compressor. The compressor draws in outside air through

1950-411: Is that the two nozzles are different sizes: the smaller nozzle is installed at a steeper angle and is used for low-rpm response, while the larger nozzle is less angled and optimised for times when high outputs are required. Variable-geometry turbochargers (also known as variable-nozzle turbochargers ) are used to alter the effective aspect ratio of the turbocharger as operating conditions change. This

2028-490: Is too small, the turbo will choke the engine at high speeds, leading to high exhaust manifold pressures, high pumping losses, and ultimately lower power output. By altering the geometry of the turbine housing as the engine accelerates, the turbo's aspect ratio can be maintained at its optimum. Because of this, variable-geometry turbochargers often have reduced lag, a lower boost threshold, and greater efficiency at higher engine speeds. The benefit of variable-geometry turbochargers

2106-441: Is unable to produce significant boost. At low rpm, the exhaust gas flow rate is unable to spin the turbine sufficiently. The boost threshold causes delays in the power delivery at low rpm (since the unboosted engine must accelerate the vehicle to increase the rpm above the boost threshold), while turbo lag causes delay in the power delivery at higher rpm. Some engines use multiple turbochargers, usually to reduce turbo lag, increase

2184-440: The 1962 , 1963 , 1964 , and 1965 seasons were won by drivers of V8-powered cars. From 1962 through 1965, the top three manufacturers in each season's Constructor's Championship all predominantly used V8 engines in their cars. In 1966, the engine capacity limits were increased to 3.0 L (183 cu in) (or 1.5 litres with a supercharger), and both the 1966 and 1967 Constructor's Championships were won by cars powered by

2262-547: The Alfa Romeo Tipo 33 racing car, and have double overhead camshafts and a dry sump. The 33 Stradale engine has a displacement of 2.00 L (122 cu in) and a flat-plane crankshaft, while the Montreal uses an engine enlarged to 2.6 L (160 cu in) and uses a cross-plane crankshaft. The 2007–2010 Alfa Romeo 8C Competizione / Spider sports cars are powered by a 4.7 L (290 cu in) version of

2340-612: The Australian Ford Falcon and Ford Fairlane models. It was also used in several low-volume DeTomaso sports cars and luxury sedans built in Italy. Australian production ceased in 1982 when Ford Australia temporarily stopped production of V8 cars. From 1991 until 2016, the Ford Falcon was available with the imported Ford Windsor , Ford Barra , or Ford Modular V8 engines; the latter was marketed as "Boss" and locally assembled from

2418-710: The Boeing B-17 Flying Fortress in 1938, which used turbochargers produced by General Electric. Other early turbocharged airplanes included the Consolidated B-24 Liberator , Lockheed P-38 Lightning , Republic P-47 Thunderbolt and experimental variants of the Focke-Wulf Fw 190 . The first practical application for trucks was realized by Swiss truck manufacturing company Saurer in the 1930s. BXD and BZD engines were manufactured with optional turbocharging from 1931 onwards. The Swiss industry played

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2496-738: The Brabham-Repco V8 engine . From 1968 until 1981, the Cosworth DFV V8 engine dominated Formula One racing. During this time, the Manufacturers' Championship was won by Cosworth DFV-powered cars every season except 1975, 1976, 1977, and 1979, which 12-cylinder Ferraris won. After a long period of dominance, the Cosworth DFV was eventually outpaced by turbocharged straight-four and V6 engines. The next period of significant V8 usage in Formula One

2574-405: The Ferrari 248 F1 . Turbocharger In an internal combustion engine , a turbocharger (also known as a turbo or a turbosupercharger ) is a forced induction device that is powered by the flow of exhaust gases. It uses this energy to compress the intake air, forcing more air into the engine in order to produce more power for a given displacement . The current categorisation is that

2652-556: The Ferrari F136 engine with a cross-plane crankshaft. Ferrari's first contact with V8 engines was the Vittorio Jano -designed 1955 Lancia-Ferrari D50 , a Formula One racing car that the company acquired as part of its purchase of Lancia's Formula One racing department. The first Ferrari-developed V8 engines were used in the 1962 Ferrari 248 SP and Ferrari 268 SP sports prototype racing cars designed by Carlo Chiti . This engine had

2730-598: The Hewitt Touring Car became the first car built in the United States with a V8 engine. The engine was designed and built by Edward R. Hewitt who emphasized the V8's superiority to the typical I4 and I6 and six-cylinder engines of the time because of its lower weight and easier to make crankshaft compared to the I6s of equal power as well as the V8 not taking much more space than a I4. The 1910 De Dion-Bouton — built in France—

2808-413: The crankshaft ) whereas a turbocharger is powered by the kinetic energy of the engine's exhaust gas . A turbocharger does not place a direct mechanical load on the engine, although turbochargers place exhaust back pressure on engines, increasing pumping losses. Supercharged engines are common in applications where throttle response is a key concern, and supercharged engines are less likely to heat soak

2886-526: The 1915 Cadillac engine. A flat-plane crankshaft is used by many V8 engines fitted to racing cars. From the gas dynamics aspect, the flat-plane crankshaft allows for even exhaust gas pulses to be achieved with a simple exhaust system. The design was popularized in motor racing by the 1961–1965 Coventry Climax FWMV Formula One engine, and the 1967–1985 Cosworth DFV engine was highly successful in Formula One. Several production sports cars have used flat-plane V8 engines, such as every Ferrari V8 model (from

2964-653: The 1939 Tatra 81 to the present day Tatra 815 . French manufacturers were pioneering in their use of V8 engines in the early 1900s with the 1904 Antoinette aircraft engine (the first known V8 engine) and the 1910 De Dion-Bouton . However, there were few French automotive V8 engines in the following decades, with manufacturers such as Delage , Delahaye , Talbot-Lago , Bugatti , and Hotchkiss using six-cylinder or straight-eight engines instead. From 1935 until 1954, Matford (Ford's French subsidiary, later renamed to ' Ford SAF ') produced cars with V8 engines, closely based on contemporary American Ford models. Simca purchased

3042-678: The 1973 Ferrari 308 GT4 to the 2019–present Ferrari F8 Tributo ), the Lotus Esprit V8 , the Porsche 918 Spyder , and the McLaren MP4-12C . The first V8 engine used in a road-going car was the 1905 Rolls-Royce built in the United Kingdom. This model was initially equipped with a 3.5 L (214 cu in) V8 engine. However, only three cars were made before Rolls-Royce reverted to using straight-six engines for their cars. In 1907,

3120-414: The 1980s, as a way to increase the performance of smaller displacement engines. Like other forced induction devices, a compressor in the turbocharger pressurises the intake air before it enters the inlet manifold . In the case of a turbocharger, the compressor is powered by the kinetic energy of the engine's exhaust gases, which is extracted by the turbocharger's turbine . The main components of

3198-475: The 2019–present Ferrari F8 Tributo . Five-valve-per-cylinder versions were used from 1994 until 2005 in the Ferrari F355 and Ferrari 360 . Turbocharging was introduced on the 1984–1987 Ferrari 288 GTO flagship car, and the range of entry-level mid-engined sports cars switched to turbocharging with the 2015 Ferrari 488 . The Formula One team resumed using V8 engines for the 2006–2013 seasons, beginning with

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3276-500: The 8.2 L (500 cu in) V8 engine used in the 1971–1978 Cadillac Eldorado and BMW's 3.0 L (183 cu in) M60B30 V8 engine found in cars such as the BMW E34 530i. V8 engines intended for motorsport are often small and short-stroke to maximize RPMs and thus power. The Cosworth DFV 3.0 L (183 cu in) is such an engine. Due to its large external dimensions, V8 engines are typically used in cars that use

3354-561: The Ford SAF in 1954 and continued to produce various models powered by the Ford Flathead V8 until 1969. After WW2, France imposed very steep tax horsepower charges - the owners of cars with engines above 2 L were financially penalized, so France had a small domestic market for larger-engined cars, such as the V8. Despite this, Facel Vega produced luxury and sports cars powered by Chrysler V8 engines from 1954 through 1964. One of

3432-527: The Renault engines used by French fighter planes. Separately, testing in 1917 by the National Advisory Committee for Aeronautics (NACA) and Sanford Alexander Moss showed that a turbocharger could enable an engine to avoid any power loss (compared with the power produced at sea level) at an altitude of up to 4,250 m (13,944 ft) above sea level. The testing was conducted at Pikes Peak in

3510-550: The Stag gained its own identity until the final design shared no body panels or pressings with the 2000. The Stag was intended to use Triumph's existing 2.5-litre straight-6 engine . When the Stag design evolved into a grand tourer rather than a more conventional sports car it became clear that a more powerful, more refined engine was needed. As far back as 1963 the designer of the Triumph Slant-4 engine , Lewis Dawtrey, had foreseen

3588-688: The United States using the Liberty L-12 aircraft engine. The first commercial application of a turbocharger was in June 1924 when the first heavy duty turbocharger, model VT402, was delivered from the Baden works of Brown, Boveri & Cie , under the supervision of Alfred Büchi, to SLM, Swiss Locomotive and Machine Works in Winterthur. This was followed very closely in 1925, when Alfred Büchi successfully installed turbochargers on ten-cylinder diesel engines, increasing

3666-458: The V8 concept, initially settling on a 2.5-litre engine (in essence two 1.2-litre versions of the slant-4) with mechanical fuel injection provided by Bosch . Following the take-over of Rover by Leyland Motors in 1967 Spen King was placed in charge of product development at Triumph. The V8's Bosch fuel injection was running into numerous difficulties in development and King was unable to convince Leyland to divert extra funds to Triumph to solve

3744-402: The actual engine displacement. Engines with displacements from 6.0 to 6.6 L (366 to 403 cu in) have been classified as both small-block and big-block, depending on the particular manufacturer's range of engines. V8 engines have been used in many forms of motorsport, from Formula One , IndyCar , NASCAR , DTM and V8 Supercars circuit racing, to Top Fuel drag racing. Among

3822-511: The aluminium-conversion Chrysler 426 Hemi engine and run on highly explosive nitromethane fuel. The world's fastest non-jet-powered (i.e., piston-engine powered) wheeled land vehicle, the Speed Demon, which achieved a speed of 744.072 km/h (462.345 mph) in 2017, is powered by a V8 engine based on the Chevrolet small-block engine design. The first Australian-designed car to use

3900-449: The compressor blades. Ported shroud designs can have greater resistance to compressor surge and can improve the efficiency of the compressor wheel. The center hub rotating assembly (CHRA) houses the shaft that connects the turbine to the compressor. A lighter shaft can help reduce turbo lag. The CHRA also contains a bearing to allow this shaft to rotate at high speeds with minimal friction. Some CHRAs are water-cooled and have pipes for

3978-411: The crankshaft can be machined from a flat billet and does not require counterweights so it is lighter. However, it produces more vibration due to a secondary imbalance. Most early V8 road car engines also used a flat-plane crankshaft since this was simpler to design and build than a cross-plane crankshaft. Early flat-plane V8 engines included the 1910 De Dion-Bouton engine, the 1915 Peerless engine, and

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4056-480: The cylinderheads to be removed (in design, not in reality) without firstly removing the overhead camshafts and disturbing the valveplay adjustment. The water pump, oil pump and distributor were all driven at their required speeds from a single jackshaft driven from the timing chain via sets of skew-cut gears. The cooling fan was a 16-blade plastic item driven through a hydraulic viscous coupling that limited fan speed to 2,500 rpm to reduce noise as well as controlling

4134-403: The engine rpm is within the turbocharger's operating range – that occurs between pressing the throttle and the turbocharger spooling up to provide boost pressure. This delay is due to the increasing exhaust gas flow (after the throttle is suddenly opened) taking time to spin up the turbine to speeds where boost is produced. The effect of turbo lag is reduced throttle response , in

4212-559: The engine's coolant to flow through. One reason for water cooling is to protect the turbocharger's lubricating oil from overheating. The simplest type of turbocharger is the free floating turbocharger. This system would be able to achieve maximum boost at maximum engine revs and full throttle, however additional components are needed to produce an engine that is driveable in a range of load and rpm conditions. Additional components that are commonly used in conjunction with turbochargers are: Turbo lag refers to delay – when

4290-418: The engine's intake system, pressurises it, then feeds it into the combustion chambers (via the inlet manifold ). The compressor section of the turbocharger consists of an impeller, a diffuser, and a volute housing. The operating characteristics of a compressor are described by the compressor map . Some turbochargers use a "ported shroud", whereby a ring of holes or circular grooves allows air to bleed around

4368-466: The fan speed in relation to engine temperature. Triumph originally intended their V8 to be used across their range, which was the reason for the company's willingness to fund the engine's high development costs. Plans were made to create a 'Triumph 3000' by fitting the engine into the 2000 saloon, but these plans were halted when Rover joined Triumph in the Leyland grouping as the resulting car would have been

4446-456: The first German V8 engines was the 1928–1945 Argus As 10 aircraft engine. This engine was air-cooled, used an 'inverted V' design, and was used in several training, surveillance, and communications airplanes. From 1933 until 1940, the Horch 830 luxury cars were powered by V8 engines (sold alongside Horch's larger straight-eight engines). Shortly after, the 1934–1937 Stoewer Greif V8 was powered by

4524-399: The first V8 Formula One cars to compete were the 1952 AFM entry and the 1954 Lancia D50 , with a development of the latter powering Juan Manuel Fangio's 1956 car to victory in the driver's championship. The 1.5 L Formula One era of 1961–1965 included V8 engines from Ferrari, Coventry Climax, British Racing Motors (BRM), and Automobili Turismo e Sport (ATS). The driver's championships for

4602-410: The flow of exhaust gases to mechanical energy of a rotating shaft (which is used to power the compressor section). The turbine housings direct the gas flow through the turbine section, and the turbine itself can spin at speeds of up to 250,000 rpm. Some turbocharger designs are available with multiple turbine housing options, allowing a housing to be selected to best suit the engine's characteristics and

4680-400: The flow of the exhaust gasses from each cylinder. In a standard (single-scroll) turbocharger, the exhaust gas from all cylinders is combined and enters the turbocharger via a single intake, which causes the gas pulses from each cylinder to interfere with each other. For a twin-scroll turbocharger, the cylinders are split into two groups in order to maximize the pulses. The exhaust manifold keeps

4758-404: The form of a delay in the power delivery. Superchargers do not suffer from turbo lag because the compressor mechanism is driven directly by the engine. Methods to reduce turbo lag include: A similar phenomenon that is often mistaken for turbo lag is the boost threshold . This is where the engine speed (rpm) is currently below the operating range of the turbocharger system, therefore the engine

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4836-523: The front) at angles of 0, 90, 270, and 180 degrees, which results in a cross shape for the crankshaft when it is viewed from one end. The rumbling exhaust sound produced by a typical cross-plane V8 engine is partly due to the uneven firing order within each of the two banks of four cylinders. A usual firing order of L-R-L-L-R-L-R-R (or R-L-R-R-L-R-L-L) results in uneven intake and exhaust pulse spacing for each bank. When separate exhaust systems are used for each bank of cylinders, this uneven pulsing results in

4914-410: The gases from these two groups of cylinders separated, then they travel through two separate spiral chambers ("scrolls") before entering the turbine housing via two separate nozzles. The scavenging effect of these gas pulses recovers more energy from the exhaust gases, minimizes parasitic back losses and improves responsiveness at low engine speeds. Another common feature of twin-scroll turbochargers

4992-499: The intake air. A combination of an exhaust-driven turbocharger and an engine-driven supercharger can mitigate the weaknesses of both. This technique is called twincharging . Turbochargers have been used in the following applications: In 2017, 27% of vehicles sold in the US were turbocharged. In Europe 67% of all vehicles were turbocharged in 2014. Historically, more than 90% of turbochargers were diesel, however, adoption in petrol engines

5070-407: The performance requirements. A turbocharger's performance is closely tied to its size, and the relative sizes of the turbine wheel and the compressor wheel. Large turbines typically require higher exhaust gas flow rates, therefore increasing turbo lag and increasing the boost threshold. Small turbines can produce boost quickly and at lower flow rates, since it has lower rotational inertia, but can be

5148-476: The possibility that the engine design could be 'doubled-up' to create a V8 unit. This was not a unique approach; Vauxhall had followed a similar strategy, designing its own slant-4 so that two could be joined to make a V8 (which, ultimately, Vauxhall did not pursue). Whilst at this point the engine had only been produced in 1.7-litre form by Triumph for sale to Saab , the basic design of the engine enabled capacities as low as 1.2-litres to be built. Triumph revived

5226-548: The power output from 1,300 to 1,860 kilowatts (1,750 to 2,500 hp). This engine was used by the German Ministry of Transport for two large passenger ships called the Preussen and Hansestadt Danzig . The design was licensed to several manufacturers and turbochargers began to be used in marine, railcar and large stationary applications. Turbochargers were used on several aircraft engines during World War II, beginning with

5304-473: The problems. Instead, King dropped the fuel injection in favour of twin Zenith-Stromberg carburetors . To maintain the required power output the capacity was increased to 3-litres, which then entailed modification to the Stag's other drivetrain systems including the gearbox , back axle and brakes . This relatively 'last-minute' capacity increase was achieved by expanding the bore of the engine instead of

5382-399: The range of rpm where boost is produced, or simplify the layout of the intake/exhaust system. The most common arrangement is twin turbochargers, however triple-turbo or quad-turbo arrangements have been occasionally used in production cars. The key difference between a turbocharger and a supercharger is that a supercharger is mechanically driven by the engine (often through a belt connected to

5460-679: The rumbling sound typically associated with V8 engines. However, racing engines seek to avoid these uneven exhaust pressure pulses to maximize the power output. The 1960s cross-plane V8 racing engines used long primary exhaust pipes (such as the Ford GT40 endurance racing car) or located the exhaust ports on the inside of the V-angle (such as the Lotus 38 IndyCar) to link the exhaust systems from each bank and provide even exhaust gas pulses),. A flat-plane crankshaft configuration provides two benefits. Mechanically,

5538-463: The stroke, which explains the Triumph V8's unusual 'oversquare' internal dimensions. As launched in 1970 the Triumph V8 had several innovative features. As well as its unusual construction (the crankcase and cylinder block were made from chromium iron whilst the cylinder heads were aluminium alloy), the engine featured a unique arrangement of studs and bolts attaching the cylinderheads that allowed

5616-407: The turbocharger are: The turbine section (also called the "hot side" or "exhaust side" of the turbo) is where the rotational force is produced, in order to power the compressor (via a rotating shaft through the center of a turbo). After the exhaust has spun the turbine it continues into the exhaust piping and out of the vehicle. The turbine uses a series of blades to convert kinetic energy from

5694-611: Was also used in touring car racing and formed the basis of the Repco-Holden engine used in Formula 5000 racing. In 1999, the Holden V8 engine began to be replaced by the imported General Motors LS1 V8 engine. In 1971, Ford Australia began local production of the Ford 'Cleveland' V8 , an overhead valve cast-iron engine. The engine was produced in displacements of 4.9 L (302 cu in) and 5.8 L (351 cu in) for use in

5772-559: Was first used on the Mercedes-Benz M113 engine in 2002 and turbocharging was first used on non-commercial diesel V8 engines in 1999 with the OM628 and on petrol engines with the M278 engine in 2010. Porsche's first road car to use a V8 engine was the 1978 Porsche 928 coupe. Its first to use a V8 diesel engine was the second-generation Cayenne S Diesel in 2014. Audi's first road car to use

5850-496: Was from 2006 to 2013 , when the rules mandated use of 2.4 L (146 cu in) naturally-aspirated V8 engines, with regular power outputs between 730 and 810 hp (in order to reduce the power outputs being achieved by the previous 3.0 litre V10 engines). These were replaced by 1.6 litre turbocharged V6 engines for the 2014 and later seasons. V8 engines have dominated American premier stock car racing NASCAR series since its inaugural 1949 season . However, there wasn't

5928-466: Was significantly increased following the 1932 introduction of the Ford Flathead V8 . By the early 21st century, the use of V8 engines in passenger vehicles declined as automobile manufacturers opted for more fuel efficient , lower capacity engines, or hybrid and electric drivetrains . The displacement of modern V8 engines is typically from 3.5 to 6.4 L (214 to 391 cu in). However, larger and smaller examples have been produced, such as

6006-488: Was the 2008–present BMW N63 engine. Their first eight-cylinder engine since passenger car and motorsport straight-eight engine production stopped in 1944 and 1955 respectively, Mercedes-Benz began production of the Mercedes-Benz M100 petrol V8 engine in 1963 and has continued production of V8 engines to the present day. The M100 had a single overhead camshaft, a cast-iron block, and an aluminium head. Supercharging

6084-643: Was the V8 remained unique to the Stag. V8 engine A V8 engine is an eight- cylinder piston engine in which two banks of four cylinders share a common crankshaft and are arranged in a V configuration . The first known V8 was the Antoinette , designed by Léon Levavasseur , and built in 1904 by the French Antoinette company for use in speedboat racing, cars, and later, airplanes. Also in 1904, V8 engines began small-scale production by Renault and Buchet for use in race cars. Most engines use

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