"V8" redirects here. For other uses, see V8 (disambiguation).
A V8 engine is an eight-cylinder V engine with the cylinders mounted on the crankcase in two sets of four cylinders, in most cases set at a right angle to each other, but sometimes at a narrower angle, with all eight pistons driving a common crankshaft.
In its simplest form, it is basically two inline-four engines sharing a common crankshaft. However, this simple configuration, with a flat- or single-plane crankshaft, has the same secondary dynamic imbalance problems as two straight-4s, resulting in vibrations in large engine displacements. Since the 1920s most V8s have used the somewhat more complex crossplane crankshaft with heavy counterweights to eliminate the vibrations. This results in an engine that is smoother than a V6, while being considerably less expensive than a V12 engine. Most racing V8s continue to use the single plane crankshaft because it allows faster acceleration and more efficient exhaust system designs.
The V8 with a crossplane crankshaft (see below) is a common configuration for large automobile engines. V8 engines are rarely less than 3.0 L (183 cu in) in displacement and in automobile use have exceeded 8.2 L (500 cu in) in production vehicles, such as the American Cadillac Eldorado for instance. In some applications, e.g. industrial and marine V8 engines, displacement can be even larger.
In automobiles V8 engines are used in a wide variety of cars, mostly they are utilized in more powerful segments and types of vehicles, such as for example the American muscle cars, and also in sports cars, luxury cars, pickup trucks, and sport utility vehicles. Many car manufacturers offer a V8 as an option in vehicles which have a V6 or straight-6 as standard engine. Hence V8-engined cars in many countries are a symbol of exclusivity and prestige, as they are only found in upscale, high-performance premium/luxury vehicles. In some cases, V6 engines were derived from V8 designs by removing two cylinders while maintaining the same V-angle so they can be built on the same assembly lines as the V8s and installed in the same engine compartments with few modifications. Some of these employed offset crankpins driving connecting rod pairs, enabling a regular firing sequence.
The traditional 90° big-bore V8 engine, as found on many American makes, is generally too wide and too long to fit in vehicles with a transverse engine front-wheel drive layout, so its applications are limited to rear-wheel drive sports cars, muscle cars, pony cars, luxury cars and light trucks. The shorter and occasionally narrower V6 engine is easier to fit in small engine compartments, but a few compact V8 engines are used in transverse FWD and transverse AWD engine configurations in larger cars, such as Cadillacs and Volvos. These engines often have tighter cylinder bore spacings, narrower cylinder bank angles, and other modifications to reduce their space requirements.
In motorsports V8s are common and have been a popular engine choice in purpose-designed engines for race-cars in many different types and classes of automotive racing, with use for example in the Formula-1 or the American NASCAR-racing league. They usually have flat-plane crankshafts, since a crossplane crankshaft results in uneven firing into the exhaust manifolds which interferes with engine tuning, and the crossplane's heavy crankshaft counterweights prevent the engine from accelerating rapidly. They are a common engine configuration in the highest echelons of motorsport, especially in the U.S. where it is required in IRL, ChampCar and NASCAR. V8 engines are also used in Australian motorsport, most notably in the V8 Supercars. Formula One began the 2006 season using naturally aspirated 2.4 L (146 cu in) V8 engines, which replaced the 3.0 L (183 cu in) V10 in a move to reduce costs and power.
Medium-weight trucks tend to use the straight-6 configuration since it is simpler and easier to maintain, and because the straight-6 is an inherently balanced layout which can be scaled up to any size necessary. Large V8s are found in the larger truck and industrial equipment lines.
Although it was the early choice for aircraft engines, the V8 engine is seldom used in modern aircraft engine as the typically heavy crankshaft counterweights are a liability. Modern light planes commonly use the flat-8 configuration instead as it is lighter and easier to air cool. In addition it can be manufactured in modular designs sharing components with flat-4 and flat-6 engines. One of the few V8 engines used for aircraft propulsion in the World War II years was the German inverted V8 configuration, air-cooled Argus As 10 powerplant.
In 1902, Léon Levavasseur took out a patent on a light but quite powerful gasoline injected V8 engine. He called it the 'Antoinette' after the young daughter of his financial backer. From 1904 he installed this engine in a number of competition speedboats and early aircraft. The aviation pioneer Alberto Santos-Dumont saw one of these boats in Côte d'Azur and decided to try it on his 14-bis aircraft. Its early 24 hp (18 kW) at 1400 rpm version with only 55 kg (121 lb) of weight was interesting, but proved to be underpowered. Santos-Dumont ordered a larger and more powerful version from Levavasseur. He changed its dimensions from the original 80 mm stroke and 80 mm bore to 105 mm stroke and 110 mm bore, obtaining 50 hp (37 kW) with 86 kg (190 lb) of weight, including cooling water. Its power-to-weight ratio was not surpassed for 25 years. Levavasseur eventually produced its own line of V8 equipped aircraft, named Antoinette I to VIII. Hubert Latham piloted the V8 powered Antoinette IV and Antoinette VII in July 1909 on two failed attempts to cross the English Channel. However, in 1910, Latham used the VII with the same engine to become the first in the world to reach an altitude of 3600 feet. Voisin constructed pusher biplanes with Antoinette engines, also, notably the one first flown successfully by Henry Farman in 1908.
The V8 engine configuration became popular in France from 1904 onward, and was used in a number of aircraft engines introduced by Renault, and Buchet among others. Some of these engines found their way into automobiles in small quantities. In 1905, Darracq built a special car to beat the world speed record. They came up with two racing car engines built on a common crankcase and camshaft. The result was monstrous engine with a displacement of 1,551 cu in (25,416 cc), good for 200 bhp (150 kW). Victor Hemery fixed that record on 30 December 1905 with a speed of 109.65 mph (176.46 km/h). This car still exists.
In 1907 The Hewitt Motor Company built a large 5 passenger Touring Car. It was equipped with a hefty V8 engine that developed 50/60 horsepower and had a bore of 4 inches and a stroke of 4 1/2 inches. The Hewitt was the first American Automobile to be equipped with a V8 engine.
De Dion-Bouton introduced a 7,773 cc (474 cu in) automobile V8 in 1910 and displayed it in New York in 1912. It was produced only in small quantities, but inspired a number of manufacturers to follow suit.
One of the first production automobile V8s was introduced in the United States in 1914 by Cadillac, a division of General Motors which sold 13,000 of the 5.4 L (330 cu in) L-head engines in its first year of production. Cadillac has been primarily a V8 company ever since. Oldsmobile, another division of General Motors, introduced its own 4 L (244 cu in) V8 engine in 1916. Chevrolet introduced a 288 cu in (4.7 L) V8 engine in 1917 and installed in the Chevrolet Series D. In February 1915, Swiss automotive engineer Marc Birkigt designed the first example of the famous Hispano-Suiza V8 single overhead cam aviation engines, in differing displacements, using dual ignition systems and in power levels from 150 horsepower to some 300 horsepower, in both direct-drive and geared output shaft versions. Almost 50,000 "Hisso" V8 powerplants in total, as the engines became nicknamed, were built in Spain, France, the United Kingdom, Italy and even by Wright Aeronautical in the United States during World War I, and from their almost-exclusive use to power the important French SPAD S.VII (about 6,000 produced) and SPAD S.XIII (nearly 8,500 produced) fighter aircraft, and the Royal Air Force's Royal Aircraft Factory S.E.5 fighters (some 5,200 built) and Sopwith Dolphin (nearly 2,100 built) fighters, the H.S. 8-series overhead cam valvetrain vee-eight aviation engines are said to have powered roughly half of all Allied aircraft of the WW I era.
By 1932, Henry Ford introduced one of his last great personal engineering triumphs: his "en block", or one piece, V8 engine. The production was the largest commercially available V8 to the masses. Offered as an option to an improved 4-cylinder Model "B" engine in a low priced car, this compact V8 power plant, with its down draft carburettor, enabled 1932 Ford to outperform all other popular competitors and was conceived as years ahead of its time. The Ford flathead V8 is still heralded today as one of the first pioneers in 'hot rod' engines.
The most prevalent V angle for a V8 is 90°. This configuration features a wide, low engine with optimal firing and vibration characteristics. Many V6 and V10 engine configurations are derived from production V8 designs, they often use the 90° angle; however, balance shafts are incorporated to reduce vibration and/or more complex cranks to even the firing cycle. V8s can use different angles. One notable example is the Ford/Yamaha V8 used in the Ford Taurus SHO. It was based on Ford's Duratec V6 and shares that engine's 60° vee angle. A similar Yamaha-built engine was used by Volvo Cars between 2005 and 2010. These engines were designed for transverse front-wheel-drive installation and are narrower than usual for efficient use of space. Because they are not at the ideal 90° angle for a V8, they require a counter-rotating balance shaft and offset split crankpins for complete smoothness. 72° V8 engines have been used in modern racing.
The Rover Meteorite V8 engine was derived from the Rover Meteor tank engine (hence derived from the Merlin aero engine), so shared the Meteor's 60° vee angle. In years past, Electro-Motive produced an 8-cylinder version of their model 567 Diesel locomotive engine, with a 45° cylinder angle. The 1932 Miller four-wheel drive race cars also featured a 45° V8.
An extremely narrow-angle V8 was introduced by Lancia in 1922, which had an angle between cylinder banks of only 14°. This created an engine that was shorter than a straight-6, but much narrower than a conventional V8. It was based on a Lancia V4 engine design that was almost completely "square" in the length and width of its layout. Because of their compact design and overhead camshafts, these engines were lighter and more powerful than comparable engines of the time. Although Lancia stopped making the V8 design around World War II, the basic concept is used today in the Volkswagen VR6 engine.
Main article: Crossplane
There are two types of 90 degree V8s which differ by crankshaft:
In 1992, Audi left the German DTM racing series after a controversy around the crankshaft design of their Audi V8 DTM. After using the road car's cross-plane 90° crankshaft for several years, they switched to a flat-plane 180° version which they claimed was made by "twisting" a stock part. The scrutineers decided that this would stretch the rules too far.
The cross-plane design was neither obvious nor simple to design. For this reason, most early V8 engines, including those from De Dion-Bouton, Peerless, and Cadillac, were flat-plane designs. In 1915, the cross-plane design was proposed at an automotive engineering conference in the United States, but it took another eight years to bring it to production. Cadillac and Peerless (who had hired an ex-Cadillac mathematician for the job) applied for a patent on the cross-plane design simultaneously, and the two agreed to share the idea. Cadillac introduced their "Compensated Crankshaft" V8 in 1923, with the "Equipoised Eight" from Peerless appearing in November 1924.
American V8 engines
Cadillac produced the first American V8 engine in a production vehicle, the 1914 L-Head. It was a sophisticated unit with cast iron paired closed-head cylinders bolted to an aluminium crankcase, and it used a flat-plane crankshaft. Peerless followed, introducing a V8 licensed from amusement park manufacturer, Herschell-Spillman, the next year. Chevrolet produced a crude overhead valve V8 in 1917, in which the valve gear was completely exposed, installed in the Chevrolet Series D. It only lasted through 1918 and Chevrolet would not produce another V8 until the introduction of the small block in 1955.
Cadillac and Peerless were one year apart again (1923 and 1924, respectively) with the introduction of the cross-plane crankshaft. Lincoln also had V8 cars in those years, as did Ferro, Northway (supplier to Cadillac), Cole (Indianapolis, and Jackson, Mississippi), Perkins (Detroit), Murray, Vernon, and Yale. Oakland, a division of GM, introduced an 85 hp (63 kW) 250 cu in (4.1 L) V8 with a 180° crankshaft in 1930–1931. In 1932, the Oakland marque was discontinued and the V8 was used in its companion marque, Pontiac, for one year. Pontiac dropped the V8 engine in 1933 and replaced it with its smoother running Silver-Streak straight eight.
Ford was the first company in the world to use V8s en masse, meaning producing them in very large quantities for use in mass-produced vehicles. Instead of going to an inline six like its competitors when something larger than an inline four was needed, Ford designed a simple V8, the Flathead of 1932. This flat head engine powered almost all larger Ford cars through the 1953 production year, and was produced until around 1970 by Ford licensees around the world, with the valve-in-block engine powering mostly commercial vehicles. The gasoline-fueled Ford GAA armored fighting vehicle engine produced from 1940 to 1950 with a capacity of 1,100 cu in (18.0 L) is the largest displacement V8 production engine to date, and was used as a power option for the U.S. Army's M4 Sherman tank in World War II.
After World War II, the strong demand for larger status-symbol cars made the common straight-6 less marketable. Straight-8 engines have problems with crankshaft whip and require a longer engine bay. In the new wider body styles, a V8 would fit in the same space as a straight-6. Manufacturers could simplify production and offer the bigger engines as optional upgrades to base models.
In 1949, General Motors (GM) responded to Ford's V8 success by introducing the Oldsmobile Rocket and Cadillac OHV. Chrysler introduced their FirePower 331 cu in (5.4 L) hemi-head V8 in 1951. That year Studebaker introduced its 232 cu in (3.8 L) OHV V8. Buick followed in 1953, while Packard and GM's Chevrolet and Pontiac introduced V8s of their own in 1955. American Motors (AMC) initially purchased V8 engines from Packard, but developed its own lower-weight, 600 lb (272 kg), design in 1956. In 2011 GM built its 100-millionth unit of the Chevrolet small-block V8, making that general engine layout (notwithstanding the various evolutions and derivatives it has seen throughout the decades that it has been built) the most produced V8 engine in the world, as well as one of the most commercially successful engines ever.
A full history of each manufacturer's engines is outside of the scope in this article, but engine sizes on full-size cars grew throughout the 1950s, 1960s, and into the early-to-mid-1970s. The increasing size of full-size cars meant smaller models of car were introduced and became more popular, with the result, by the 1960s, Chrysler, Buick, Ford, and Chevrolet had two V8 model ranges.
The larger engines, known as big-block V8s, were used in the full-size cars. Big-blocks generally had displacements in excess of 360 cu in (5.9 L). Big-block displacement reached its zenith with the 1970 Cadillac Eldorado's 500 cu in (8.2 L) 500. During the 1970s, due to the oil crises and the gradual tightening of emission-standards, big-block V8s were affected and as a result their use in passenger cars decreased as manufacturers began to phase them out over more efficient designs. However, in trucks and other larger vehicles, primarily in the North American market, big-block V8s continue to be used until today, though some manufacturers, such as for example the Ford Motor Company took a different approach and developed V10s for use in their heavy duty commercial vehicles, such as Trucks and Vans, and/or used small-block derived designs in both diesel, e.g. Powerstroke, as well as gas applications for improved power and efficiency. To this day Big-block V8s are commonly used in a wide variety of automotive racing mostly across North America, and such engines are available from many small and independent engine builders.
Smaller engines, known as small-block V8s, were fitted in the mid-size car ranges and generally displaced between 270 cu in (4.4 L) and 360 cu in (5.9 L), though some grew as large as Ford's 402 cu in (6.6 L) 400. There is overlap between big-block and small-block ranges, and a factory engine between 6.0 and 6.6 L (366 and 403 cu in) could belong to either class. Engines like this (much evolved) are still in production.
During the 1950s, 1960s, and, 1970s, every GM division had their own engines, whose merits varied. This enabled each division to have its own unique engine character, but made for much duplication of effort. Most, like the comparatively small Buick 215 and familiar Chevrolet 350, were confusingly shared across many divisions. Ford and Chrysler had fewer divisions, and quickly abandoned these division-specific engines in favour of a few shared designs. Realizing that shared designs were more cost efficient, GM also began to eliminate division-specific engines in the late 1970s, but still has never gone to a single V8 design.
Lately, Chrysler and GM have designed larger displacement V8s out of existing modern small-block V8s for use in performance vehicles, such as Chrysler's 6.1 L (372.2 cu in) and 6.4 L (390.6 cu in) Hemis, and the LS7 7.0 L (427.2 cu in) version of GM's LS engines.
Today, professional racing V8s are still common with American cars. Track cars commonly use naturally aspirated, turbocharged or supercharged engines around 4–7 L (240–430 cu in) in size. Pro-stock and Superstock drag racing engines usually use big-block (400–600 cu in (6.6–9.8 L)) Chevrolet or Ford Boss engines, some upwards of 800 cu in (13.1 L), and one 1,005 cu in (16.5 L) General Motors engine engineered by Sonny Leonard Racing which can rev to 8000 rpm. Top Fuel/Funny cars generally uses aluminum-conversion Chrysler Gen II Hemi. Superchargers for the engines are based on "blowers" used to scavenge spent exhaust gases from large 2-stroke diesel engines, such as the Detroit Diesel. There is also a Ford 500 cu in (8.2 L) Boss Top Fuel/Funny car engine.
Australian V8 engines
The Australian V8 is typically an American-manufactured block from either Ford, Chrysler or General Motors yet often uses local heads and auxiliary systems (pistons, exhaust etc.). However, there are a couple of exceptions to this - the Holden V8 engine small block V8, and the British Leyland alloy small-block V8.
The Holden small-block V8 was an all Australian designed and manufactured cast-iron 90° pushrod OHV engine, manufactured in the capacities of 4.2 L (253 CID), 5.0 L (308 CID, later destroked to 304 CID), and 5.7 L (355 CID - Produced by Holden Special Vehicles, never actually built as a 'production' motor). First introduced in 1969, ceasing production in 1999, it powered a variety of Holden vehicles including the Kingswood, Monaro, Torana and Commodore, and proved to be a popular and successful powerplant in Australian motorsport (especially Touring cars). Repco also developed and built the Repco-Holden Formula 5000 engine for Formula 5000 racing. Repco used the block and head castings of the Holden 308 V8 engine as its basis, but it featured many modifications including Lucas fuel injection and dual coil Bosch ignition and more than 150 special components designed by Repco.
The British Leyland small block V8 was also a pushrod OHV engine, however it was an all alloy block like the American Buick/British Rover V8 it was based on. The stroke was increased to give it a capacity of 4.4 L (270 cu in). The motor was originally designed and fitted to the Leyland P76 sedan.
As of 2014, the only V8 produced in Australia is the 5.0L V8 built by Ford Performance Vehicles to power its FPV GT & GS models. This motor is a combination of US-sourced and locally manufactured parts. The V8 used in current Holdens is sourced complete from GM in Canada, modified versions of the GM LS-series engine.
When U.S. production of the Cleveland V8 range ceased in the early 1970s, the tooling was moved to Australia where Ford Australia continued to produce a local version of the 351 and a unique-to-Australia 302 Cleveland. The Australian-built motors were also sold to De Tomaso to be used in the Pantera and Longchamps. Australian production ceased in 1982, with the last Cleveland-powered Falcon being the XE range (1400-odd 302s and 409 351s).
British V8 engines
The Rolls-Royce V-8 was the first British V8. It is a 3.5 L (214 cu in) square engine with side valves and a 90° angle. To compete with electric cars, the engineering priorities of this engine were quietness and refinement over outright power and the design was deliberately shallow to emulate the look of the town brougham.
A later Rolls-Royce V8 was the Meteorite, an armoured vehicle and marine engine derived from the V12 Rolls-Royce Meteor tank engine by using two-thirds of the Meteor's cylinders, the Meteor itself being developed from the Merlin aero engine.
In the twenty-first century, Aston Martin, Bentley, Jaguar, Land Rover, McLaren and Radical all continue to manufacture V8 engines.
The AJ-V8 featured on Ward's 10 Best Engines list in 2000. It has been fitted extensively to all of Jaguar's recent executive, luxury and sports cars where it replaced both the AJ6 and V12 units. The AJ-V8 can also be found some upmarket Ford and Lincoln models as well as in David Brown Automotive's Speedback GT and Land Rovers, including a unique to Land Rover 4.4 L (269 cu in) capacity.
It is still used in modern Bentleys today (and is the world's longest-lived car engine) but began life in the Rolls Royce Silver Cloud and Bentley S2. Early versions were of 6.25 L (381 cu in) displacement, growing to 6.75 L (412 cu in) in the 1970s. Turbocharging in various Bentley models beginning in the 1980s led to the resurgence of the Bentley marque as the power outputs of the engine were increased in several steps. It currently produces 530 bhp (400 kW) and 1,100 N·m (810 ft·lb) in the Bentley Mulsanne Speed, while meeting Euro 6 and LEV II emissions standards. It wasn't until 2007 that the final components which could be traced back to the 1959 engine were replaced.
For passenger vehicles, Rover was in need of a new, more powerful engine by the mid-1960s. The managing director of Rover, on a trip to America where he saw an example of the Buick 'Small Block' 215 engine in the Mercury Marine experimental department and was impressed with its light weight and small size relative to its power output and potential. The 3.5 L (214 cu in) V8 was only 12 pounds (5.4 kg) heavier and less than 1 inch (2.5 cm) longer than the 2.0 L (122 cu in) Rover straight-4. He sent the aluminium engine back to the U.K. for evaluation. It worked well in the large Rovers, being considerably shorter, lighter, and more powerful than the Rover straight 6, and Rover acquired manufacturing rights to it. The engine first appeared in Rover saloons in the late 1960s.
As well as appearing in Rover cars, the engine was also sold to small car manufacturers. Morgan, TVR, Triumph, Marcos, and MG, among others all bought the engine. Land Rover also used the V8, appearing in the Land Rover Discovery and Range Rover in various guises, from 3.5 L (214 cu in) in the earlier models to the 4.6 L (281 cu in) used in the 1994–2002 models. Many independent sports cars manufacturers still use it in hand-built applications.
The allure of the 'Rover V8' moniker was considered to be so strong that MG Rover decided to re-engineer the Rover 75 in 2002 to fit a 4.6 L (281 cu in) V8 engine. As the original Rover V8 had ended production, the Ford Modular V8 was fitted instead.
Chinese V8 engines
Czech V8 engines
Tatra used their air-cooled V8 engines from 1934, when introduced Tatra 77 (first serial-produced aerodynamically designed car). These culminated in the 2.5 L unit used in the Tatra T603 range of cars. The most powerful of these was fitted to the racing variant - known as the B-5. This was a higher compression version of the standard engine which replaced a standard single 2BBL carburettor with two 4BBL downdraft units on a new induction manifold. Tatra later produced another air-cooled engine, used in Tatra 613 and later, in Tatra 700. These engines were well known for their reliability, good fuel consumption, and specific sound.
In the Tatra 603, two engine driven fans help pull cooling air into the engine bay - when the vehicle is in motion the air enters through intakes in the rear wing panels and is exhausted through cut-outs below the bumper and alongside the engine itself. In the Tatra 613, one large ventilator pushes fresh cold air into the engine bay.
Tatra has used V8 air-cooled engines in their heavy duty trucks until the present day in their Tatra 815 and other models.
French V8 engines
While France developed the very first V8 engines, they used it for pioneer era airplanes before 1910. The French De Dion-Bouton motorcar firm did produce a V8 engine for sale in a car in 1910. During the collectible, Art Deco age of French automobiles in the 1920-30's, makes like Delage, Delahaye, Talbot-Lago, Bugatti and Hotchkiss et Cie used Inline-6 and Inline-8 cylinder engines.
Ford Société Anonyme Française built V8 powered cars (to a U.S. design) through its Matford subsidiary in Strasbourg, France from 1935 to 1954. After WW2, the vehicles badged Ford. Simca purchased Ford SAF in 1954,including the rights to continue building the V8, in the Simca Vedette. Facel, a bodywork subcontractor to Ford SAF,also built V8 cars, using Chrysler engines, from 1954 to 1964.
After WW2, France imposed very steep Tax horsepower charges - the owners of cars with engines above 2 liters were financially penalized, so France had a very small domestic market for larger engined cars, such as the V8.
Both the Citroën SM and the "PRV" (Peugeot, Renault, Volvo) V6 were effectively 90 degree V8 motors, with two cylinders removed. An SM V8 was created as a test bed for the 1975 Maserati Quattroporte that never saw full-scale production, due to the 1974 bankruptcy of Citroën. This car was fully developed and suitable for road use. The 1973 oil crisis made a French car with a V8 engine even more difficult to rationalize.
France does not currently build any V8 powered cars.
German V8 engines
German companies that have manufactured V8 engines include Argus Motoren, Argus As 10 who produced an inverted V8 air-cooled aircraft engine from 1928 to 1945; Horch introduced the V8 Powered 830 Series in 1933 as a smaller alternative to their inline-8 powered models. Other firms include Audi, (VAG) who have produced a range of V8 petrol engines since 1988; BMW; Horch; Mercedes-Benz, who have produced both petrol and diesel versions; Porsche and Stoewer.
In the early 1960s, Mercedes-Benz introduced the first post-WWII V8 engine by a German/European manufacturer with their M100 engine, which was first used in the 600 Pullman Limousine and later in their high-end luxury sedans, e.g. the 300 SEL 6.3. The successor to the M110, the M116 and M117 were the standard power plant in the R/C-107 Roadster/Coupe and the W116 "Big Benz" 4 doors.
Italian V8 engines
Arguably, Ferrari had their first contact with V8 power with the "inherited" Lancia D50s in 1955. Ferrari adopted the V8 configuration for themselves for racing in 1962 with the 268 SP. The first V8-powered Ferrari road car was 1974's 308 GT4, with the familiar 308 GTB following closely behind. The company continued to use this Dino V8 engine ever since with the 328, 348, and successors. Ferrari's smallest V8 (and indeed, the smallest ever) was the 2.0 L (1990 cc) unit found in the 1975 208 GT4. The company produced a slightly larger 2.0 L V8 in the 208 GTB and the 2.9 L Ferrari F40 of the 1980s. This was a turbocharged engine to reduce the road tax of the car in Italy. Automobiles with engines displacing more than 2.0 Litre were subject to a much higher tax rate. Five-valve-per-cylinder versions of Ferrari's 3.5 L and 3.6 L V8s were found in the Ferrari F355 and Ferrari 360. The old Dino V8 was retired for 2004 with the introduction of a 4.3 L V8, based on the originally Ferrari designed Maserati 4.2 V8, in the F430 and the California. And F430's successor, 458 Italia, with 4.5 V8.
Maserati have used V8s for many of their models, including the Maserati Bora and the Maserati Khamsin. This engine was initially designed as a racing engine for the Maserati 450S. The company's latest 4.2 L V8, found in the Maserati Quattroporte and Maserati Coupé & Spyder was originally designed by Ferrari, and is related to the 4.3 L V8 in the F430.
Japanese V8 engines
Japanese manufacturers are traditionally not known for V8 engines in their roadcars. However, they have built a few V8 engines to meet the needs of consumers, as well as for their own racing programs. In Japan, V8 engines are regarded as an expensive luxury item, due to Japanese Government engine displacement regulations that impose a yearly annual tax for engines that exceed 2000cc. Most Japanese manufacturers have introduced and installed 2.0L V6 engines in large Japanese vehicles that are adequately powerful, making a 2.0 L V8 impractical.
However, Honda has built V8s for racing, most notably for Formula One. Honda was the sole engine builder for Indy Racing from 2006 through 2011. The Honda Indy V8 has a 10,300 rpm redline. Also, their affiliate Mugen Motorsports (now known as M-Tec) has built racing V8s that eventually found their way into limited production road cars as well as concept cars. Their MF408S engine, which powers cars in the ALMS, is also found in prototype racers such as the Mooncraft Shiden. It is the engine in the Honda Legend based Honda Max concept.
Korean V8 engines
Swedish V8 engines
The most well-known Swedish V8 engine producer, is probably the Scania AB, with the 14 L (854 cu in) diesel, which was released in 1969 for use in the 140 model heavy trucks. At this point, the 350 hp (261 kW) turbo-charged engine was among the most powerful diesel engines offered in Europe. Scania continues using a V8 as its largest displacement engine at 16 L (976 cu in) producing maximum 730 hp (544 kW), for the R-series, G-series, and P-series (in buses and coaches he uses I6). Emission norms range between Euro 3-Euro 6 depending on which market the vehicle is sold to.
Volvo's 1950s concept car Philip also had a gasoline V8 engine. The car never went into production, but the engine evolved into a 120 hp 3.6 L V8 (in many aspects a "double B18" engine) for use in the light trucks Volvo Snabbe and Volvo Trygge from the late 1950s on.
Small scale Supercar manufacturer Koenigsegg has developed a 5.0 L (305 cu in) twin-turbocharged V8 producing 1140 bhp for use in their Agera models. This engine is unique in that it is a flexible fuel engine and produces more power while running on biofuel than on regular unleaded. Previously Koenigsegg utilized a Ford Powerplant, namely the Ford Modular 4.7L V8.
Soviet V8 engines
ZIL-114 (1967) was powered by a 6,960 cc (425 cu in) V8 giving 300 hp (224 kW) at 4400 rpm. Its more modern derivative model, the ZIL-41047, is powered by a ZIL-4104 engine, a 7680 cc carburetted V8 giving 315 hp (235 kW) at 4600 rpm.
The ZIL trucks used (and still use) a modification of this engine (cast-iron block, aluminum heads, 6L, 150 hp (112 kW) at 3200 rpm, 6.5:1 compresson rate, one 2-bbl carburetor).
Several cars produced under the Volga brand name: the GAZ-23 (1962–1970), GAZ-24-24 V8 (1974–1992), and GAZ-31013 V8 (1982–1996). In addition, both generations of the GAZ Chaika limousines (1959–1982 and 1976–1988) were powered by an all-aluminum OHV 5.5L V8. These engines were designated ZMZ-13 (GAZ-13), one 4-bbl carburetor), ZMZ-14 (GAZ-14), two 4-bbl carburetors), ZMZ-2424 (Volga GAZ-24-24), ZMZ-505 (two 4-bbl carburetors) and -503 (one 4-bbl carburetor) (GAZ-24-34, GAZ-31013). Power output varied from 195–220 hp (145–164 kW). A modification of the same engine was also used in the BRDM-2 military armored vehicle, designated ZMZ-41.
The GAZ-53 was powered by a 4,254 cc (259.6 cu in) ZMZ-53 engine, which substantially was a modification of the Chaika's engine with one 2-bbl carburetor and decreased displacement and compression ratio. More modern version of the GAZ engine for intermediate trucks is designated ZMZ-511.
Spanish V8 engines
The Z-102 first introduced in 1951 engine was an advanced design sporting quadruple camshafts (two per bank) and had 2 valves per cylinder. It was available with 1, 2 or 4 twin Weber carburettors and either normally aspirated or with one or two superchargers. It had three different capacities, 2472 cc (151 CID), 2816 cc (172 CID) and 3178 cc (194 CID) and made between 165 bhp (123 kW) and 360 bhp (270 kW).
The Z-103/4 developed in the mid/late 1950s (the first prototype was made in 1954) was a much simpler design destined to power a new series of luxury and sportscars. It had a single central camshaft and 2 valves per cylinder actuated by pushrods. It had hemispherical combustion chambers (like the Z-102 engine) and twin spark plugs. It was available with three different cubic capacities as well, 3900 cc (238 CID), 4500 cc (275 CID) and 4700 cc (287 CID). The 3.9 L engine had a twin Weber carburettor and the 4.5 and 4.7 L engines 2 quadruple Weber carbs, which gave the later a power output in excess of 300 bhp (220 kW). The very few engines of this type produced were installed in Z-102 cars.
Other V8 applications
In aviation, V8 engines have been used by a variety of applications such as the Argus As 10 inverted, air-cooled German V8 engine of World War II; the Hispano-Suiza 8 of World War I V8; the American Liberty L-8 of World War I, 45° V8 (a prototype for the Liberty L-12); and the American Trace Engines Turbocharged V8 aviation engine.
There are numerous marine diesel engines of V8 configuration including the Brons V8 two-stroke diesel engine, and engines by Scania and Yanmar. However, the configuration is not common in large marine engines. In June 2015, Wärtsilä published a new engine type (Wärtsilä 31) which is also available in V8 configuration. The 8V31 weighs 56 metric tons and is rated at 4,880 kilowatts (6,540 hp).
Moto Guzzi of Italy built a 148 kg (326 lb) 82 bhp (61 kW) water-cooled DOHC V8 4-stroke motorcycle for Grand Prix racing between 1955 and 1957, referred to as the Moto Guzzi Grand Prix 500 cc V8. It was known as the Otto Cilindri, and had a very high power output but was not developed to its full potential. Each cylinder had its own carburetter.
Around 1964, Finnish TT motorcyclist technician area lecturer Tauno Nurmi built a 350 cc DOHC V8-powered 4-stroke motorcycle engine by the name V8 PREMIER. V angle is 90° and it is air-cooled. Each cylinder has its own carburettor. It is his own design and construction.
Morbidelli produced an 848 cc V8 in 1994. Earlier, Galbusera had produced a two-stroke V8 in 1938.
Honda released the NR750 in 1992. The bike had a 750 cc V4 with oval pistons, utilising 8 valves per cylinder and 2 conrods per piston; the design allowed the engine to meet FIM racing regulations limiting the number of cylinders to 4, while providing the valve area (and therefore increased efficiency) of a V8.
See also: Cosworth DFV
For the 2.5 L Formula One era of 1954–1960, two British racing V8s were built in Coventry. One was the Coventry Climax FPE named the Godiva, and the other was the little-known Brooke Weston. Because of Coventry Climax's decision not to release the engine to Kieft, HWM and Connaught at the time, the Godiva did not debut until 1966 when it raced under the 3 Litre formula on Shannon F1 at the British GP with an enlarged 3 Litre displacement. Brooke Weston DOHC V8 was scheduled to be installed on an ERA, but this did not materialise due to Leslie Johnson's declining health prompted the sale of ERA, which pulled out of the project.
Lancia raced Vittorio Jano designed V8 DS50 engine on Lancia D50 in 1954. When Lancia withdrew from racing in 1955, Ferrari bought the Lancia team and continued to develop it. Juan Manuel Fangio won the 1956 World Drivers' Championship in the DS50-powered Ferrari-Lancia D50.
The 1.5 L Formula One era of 1961–1965 included V8 engines from Ferrari, Coventry Climax, BRM, and ATS. Ferrari, BRM and ATS used their engines in their cars, while Coventry Climax and BRM sold engines to constructors. Apart from Phil Hill's 1961 World Drivers' Championship, which he won in a V6-powered Ferrari, all the other World Drivers' Champions (Graham Hill in 1962, Jim Clark in 1963, John Surtees in 1964, and Clark again in 1965) drove V8-powered cars to their victories. Also, from 1962 to 1965, the top three manufacturers in each season's Manufacturer's Championship all predominantly used V8 engines in their cars.
The first two seasons of the 3.0 L normally aspirated/1.5 L supercharged Formula One era of 1966–1986 were won by Brabham cars with Repco V8 engines. From 1968 to 1981, F1 was largely dominated by teams using the Cosworth DFV engine. During this time, the Manufacturers' Championship was won by Cosworth DFV powered cars every season except 1975, 1976, 1977, and 1979, which were won by 12-cylinder Ferraris. Graham Hill, Jochen Rindt, James Hunt, Mario Andretti, Alan Jones, Nelson Piquet, and Keke Rosberg each won a World Drivers' Championship in a Cosworth DFV powered car, while Emerson Fittipaldi won two and Jackie Stewart won three.
Throughout the 1970s the Cosworth V8 faced stiff competition from the V12/Flat 12 engines of Matra, Ferrari and Alfa Romeo. However, because of the 90 degree V8 design of the Cosworth, it was much lighter, simpler, more fuel efficient and more compact than its 12-cylinder rivals. What kept the Cosworth V8 competitive was because it was a compact, narrow engine it had less frontal area than a V12/flat 12, giving the teams who used it better aero balance resulting in better downforce and straightline speed. In the late-1970s, Lotus used "ground effect" venturi tunnels with "sliding skirts" to enhance roadholding and the Lotus 79 powered by the FV V8 dominated the 1978 season, ending Ferrari's three year dominance of the constructors championship. The Ligier and Brabham also switched from bulky heavy V12s to the DFV during the 1979/1980 seasons. The 15-year-old Cosworth DFVV was narrow and fit the ground effects better than the Ferrari flat 12. The British kit car teams used the old engine to exploit ground effect to win the drivers championship in 1978, 1980, 1981, and 1982.
Between the years 1995 and 2005, all Formula One cars used engines with a 3-litre displacement, by 2005 these were all V10s. Later regulations and safety concerns by the FIA considered speeds were getting too high to be safe, after the complete banning of turbochargers in 1989, the permitted engine size was further reduced to 2.4 L V8. This reduced average power output of the engines from 900 bhp (670 kW), in the 2005 season, to a 2006 season average of approx. 650–750 bhp (480–560 kW) - equivalent to power outputs that were being achieved on 3 L around the 1999/2000 seasons. This also had the effect of reducing overall costs for the teams, an aim pursued by FIA.
In the American 'Top Fuel' class of Drag Racing, V8 engines displacing 500 cu in (8 L) today produce outputs of over 10,000 hp (7,457 kW; 10,139 PS), (1000+hp per cylinder) and 7,400 foot-pounds of torque Based on the Chrysler Hemi and running on highly explosive Nitro-Methane fuel, these powerful units propel the cars from 0-100 mph in 0.8 seconds or less, and from 0–325 mph (0–523 km/h) in under 4.5 seconds.
American premier stock car racing NASCAR series has been dominated by American V8 engines since the introduction of the Oldsmobile Rocket 88 engine.
The world's fastest non-jet-powered i.e. piston engine wheeled land vehicle, the Speed Demon, which achieved a speed of 462.345 mph, is powered by an American v8 engine. The vehicle utilizes highly modified V8 engines based on the Chevy small-block architecture, ranging in size from 299 to 388 cubic inches, with power outputs from 1980 hp for the smallest unit i.e. the 288 cui , to 2670 hp and 1310 lb. -ft. of torque for the 388 cui unit.
British BriSCA F1 Stock Cars (and their counterparts from the Netherlands) use American V8 engines for racing; typically Chevrolet small blocks for tarmac tracks and big blocks, displacing as much as 590 cu in (10 L), for racing on shale ovals. V8 Hotstox, which often run at the same fixtures as BriSCA F1 stock cars, tend to use Rover V8 engines of approximately 3.5 litre capacity.
Afrikaans V8-enjin ▪ Български V8 двигател ▪ Čeština Osmiválec ▪ Dansk V8-motor ▪ Deutsch Achtzylinder ▪ Español Motor V8 ▪ Français Moteur V8 ▪ Galego Motor V8 ▪ हिन्दी वी8 इंजन ▪ Hrvatski V8 motor ▪ Bahasa Indonesia Mesin V8 ▪ Italiano Motore V8 ▪ Latviešu V8 dzinējs ▪ Lietuvių V8 ▪ Bahasa Melayu Enjin V8 ▪ Dorerin Naoero V8 ▪ 日本語 V型8気筒 ▪ Norsk bokmål V8-motor ▪ Polski V8 (silnik) ▪ Português Motor V8 ▪ Simple English V8 engine ▪ Slovenčina Osemvalcový vidlicový motor ▪ Slovenščina V8 ▪ Suomi V8-moottori ▪ Svenska V8 ▪ Türkçe V8 Motoru ▪ Vèneto V8 ▪ 中文 V8发动机 ▪
Source of information: Wikipedia, the free encyclopedia. We're not responsible for the content of this article and your use of this information. Disclaimer