Inline-four engine

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Ford inline-four engine with cylinder head removed
A cutaway Renault-Nissan M9R 2.0L Straight-4 DOHC Common rail diesel engine

The inline-four engine or straight-four engine is an internal combustion engine with all four cylinders mounted in a straight line, or plane along the crankcase. The single bank of cylinders may be oriented in either a vertical or an inclined plane with all the pistons driving a common crankshaft. Where it is inclined, it is sometimes called a slant-four. In a specification chart or when an abbreviation is used, an inline-four engine is listed either as I4 or L4 (for longitudinal, to avoid confusion between the digit 1 and the letter I).

The inline-four layout is in perfect primary balance and confers a degree of mechanical simplicity which makes it popular for economy cars.[1] However, despite its simplicity, it suffers from a secondary imbalance which causes minor vibrations in smaller engines. These vibrations become worse as engine size and power increase, so the more powerful engines used in larger cars generally are more complex designs with more than four cylinders.

Today almost all manufacturers of four-cylinder engines for automobiles produce the inline-four layout, with Subaru's Flat-four engine being a notable exception, and so four-cylinder is synonymous with and a more widely used term than inline-four. The inline-four is the most common engine configuration in modern cars, while the V6 engine is the second most popular.[2] In the late 2000s, with auto manufacturers making efforts to reduce emissions; and increase fuel efficiency due to the high price of oil and the economic recession, the proportion of new vehicles sold in the U.S. with four-cylinder engines (largely of the inline-four type) rose from 30 percent to 47 percent between 2005 and 2008, particularly in mid-size vehicles where a decreasing number of buyers have chosen the V6 performance option.[3][4]

Contents

Displacement

This inline engine configuration is the most common in cars with a displacement up to 2.4 L. The usual "practical" limit of the displacement of inline-four engines in a car is around 2.7 L. However, Porsche used a 3.0 L four in its 944 S2 and 968 sports cars, the International Harvester Scout was available with a 3.2 L inline four from 1965 until 1980 and Rolls-Royce produced several inline-four engines of 2,838 cc with basic cylinder dimensions of 3.5 in (89 mm) diameter and 4.5 in (110 mm) stroke (Rolls-Royce B40). Early vehicles also tended to have engines with larger displacements to develop horsepower and torque. The Model A Ford was built with a 3.3 L inline-four engine.

Inline-four diesel engines, which are lower revving than gasoline engines, often exceed 3.0 L. Mitsubishi still employs a 3.2 L inline-four turbodiesel in its Pajero (called the Shogun or Montero in certain markets), and Tata Motors employs a 3.0 L inline-four diesel in its Spacio and Sumo Victa.

The Toyota B engine series of diesel engines varies in displacement from 3.0- 4.1 L. The largest engine in that series was used in the Mega Cruiser.

One of the strongest Powerboat-4-cylinders is the Volvo Penta D4-300 turbodiesel. This is a 3.7 L-inline-4 with 300 hp (224 kW) and 516 lb·ft (700 N·m) .[5]

One of the strongest inline-4-engines is the MAN D0834 engine. This is a 4.6 L inline-4 with 220 hp (164 kW) and 627 lb·ft (850 N·m), which is available for the MAN TGL light-duty truck and VARIOmobil motorhomes.[6]

The Isuzu Forward is a medium-duty truck which is available with a 5.2 L inline-four engine that delivers 210 hp (157 kW) and 470 lb·ft (640 N·m) .[7]

The Hino Ranger is a medium-duty truck which is available with a 5.1 L inline-four engine that delivers 175 hp (130 kW) and 465 lb·ft (630 N·m) .[8] The earlier Hino Ranger even had a 5.3 L inline-four engine.[9]

The Kubota M135X is a tractor with a 6.1 L inline-four. This turbo-diesel engine has a bore of 118 mm (4.6 in) and a relative long stroke of 140 mm (5.5 in).[10]

Larger inline-four engines are used in industrial applications, such as in small trucks and tractors, are often found with displacements up to about 4.6 L. Diesel engines for stationary, marine and locomotive use (which run at low speeds) are made in much larger sizes.

Brunswick Marine built a 127 kW (170 bhp) 3.7 L 4-cylinder gasoline engine (designated as the "470") for their Mercruiser Inboard/outboard line. The block was formed from one half of a Ford 460 cubic inch V8 engine. This engine was produced in the 1970s and 1980s.Template:Citation needed

One of the largest inline-four engines is the MAN B&W 4K90 marine engine. This two-stroke turbo-diesel has a giant displacement of 6,489 L. This results from a massive 0.9 meter bore and 2.5 meter stroke. The 4k90 engine develops 18,280 kW (24,854 PS; 24,514 hp) at 94 rpm and weighs 787 tons.[11]

Displacement can also be very small, as found in kei cars sold in Japan, such as the Subaru EN series; engines that started out at 550 cc and are currently at 660 cc, with variable valve timing, DOHC and superchargers resulting in engines that often claim the legal maximum of 64 PS (47 kW; 63 bhp).

Balance and smoothness

Computer generated image showing the major internal moving parts of an inline-four engine with belt-driven double overhead camshafts and 4 valves per cylinder.

The inline-four engine is much smoother than one-, two-, and three-cylinder engines, and this has resulted in it becoming the engine of choice for most economy cars, although it can be found in some sports cars as well. However, the inline-four is not a fully balanced configuration.

An even-firing inline-four engine is in primary balance because the pistons are moving in pairs, and one pair of pistons is always moving up at the same time as the other pair is moving down. However, piston acceleration and deceleration are greater in the top half of the crankshaft rotation than in the bottom half, because the connecting rods are not infinitely long, resulting in a non sinusoidal motion. As a result, two pistons are always accelerating faster in one direction, while the other two are accelerating more slowly in the other direction, which leads to a secondary dynamic imbalance that causes an up-and-down vibration at twice crankshaft speed. This imbalance is tolerable in a small, low-displacement, low-power configuration, but the vibrations get worse with increasing size and power.[12]

The reason for the piston's higher speed during the 180° rotation from mid-stroke through top-dead-centre, and back to mid-stroke, is that the minor contribution to the piston's up/down movement from the connecting rod's change of angle here has the same direction as the major contribution to the piston's up/down movement from the up/down movement of the crank pin. By contrast, during the 180° rotation from mid-stroke through bottom-dead-centre and back to mid-stroke, the minor contribution to the piston's up/down movement from the connecting rod's change of angle has the opposite direction of the major contribution to the piston's up/down movement from the up/down movement of the crank pin.

Most inline-four engines below 2.0 L in displacement rely on the damping effect of their engine mounts to reduce the vibrations to acceptable levels. Above 2.0 L, most modern inline-four engines now use balance shafts to eliminate the second-order harmonic vibrations. In a system invented by Dr. Frederick W. Lanchester in 1911, and popularised by Mitsubishi Motors in the 1970s, an inline-four engine uses two balance shafts, rotating in opposite directions at twice the crankshaft's speed, to offset the differences in piston speed.[13] However, in the past, there were numerous examples of larger inline-fours without balance shafts, such as the Citroën DS 23 2,347 cc engine that was a derivative of the Traction Avant engine, the 1948 Austin 2,660 cc engine used in the Austin-Healey 100 and Austin Atlantic, the 3.3 L flathead engine used in the Ford Model A (1927), and the 2.5 L GM Iron Duke engine used in a number of American cars and trucks. Soviet/Russian GAZ Volga cars and UAZ SUVs, vans and light trucks used aluminium big-bore inline-four engines (2.5 or later 2.9 L) with no balance shafts from the 1950s-1990s. These engines were generally the result of a long incremental evolution process and their power was kept low compared to their capacity. However, the forces increase with the square of the engine speed — that is, doubling the speed makes the vibration four times worse — so modern high-speed inline-fours have more need to use balance shafts to offset the vibrations.[14]

Four-cylinder engines also have a smoothness problem in that the power strokes of the pistons do not overlap. With four cylinders and four strokes to complete in the four-stroke cycle, each piston must complete its power stroke and come to a complete stop before the next piston can start a new power stroke, resulting in a pause between each power stroke and a pulsating delivery of power. In engines with more cylinders, the power strokes overlap, which gives them a smoother delivery of power and less vibration than a four can achieve. As a result, six- and eight- cylinder engines are generally used in more luxurious and expensive cars.

Automobile use

Notable production inline-four engines

1970 Alfa Romeo 1750 GTV engine

The smallest automobile production inline-four engine powered the 1962-1970 Mazda P360 Carol kei car.Template:Citation needed Displacing just 358 cc, the Mazda DA was a conventional but tiny pushrod engine. Honda produced, from 1963 to 1967, a 356 cc (21.7 cu in) inline-four engine for the T360 truck. Inline-four motorcycle engines are built down to 250 cc, e.g. in the Honda CBR250.

Most inline-four engines, however, have been over 700 cc (43 cu in) displacement. A practical upper limit could be placed in the 2.5 L range for contemporary production cars. Larger engines (up to 6.1 L) have been seen in tractors (Kubota M135X) and medium duty truck use (Isuzu Forward, Hino Ranger), especially using diesel fuel (one of the strongest is the MAN D0834 engine with 220 hp (164 kW) and 627 lb·ft (850 N·m) [15]). The use of balance shafts allowed Porsche to use a 3.0 L (2990 cc) inline-four engine on road cars first in the 944 S2, but the largest modern non-diesel was the plain 3,188 cc (194.5 cu in) 195 in the 1961 Pontiac Tempest.

Currently, one of the largest straight-4 engines in production is General Motors' Vortec 2900 installed in the GMC Canyon and Chevrolet Colorado small pickup trucks. It shares the same 95.5 mm (3.8 in) bore and 102 mm (4.0 in) stroke as the larger inline-five Vortec 3700. The latest version of the Vortec 2900, the LLV, displaces 2.9 L (2921 cc, 178 in³) and produces 185 hp (138 kW) at 5600 rpm and 195 lb·ft (264 N·m) at 2800 rpm. Engine redline is 6300 rpm. Another example of a large inline-four engine is the Russian 2.89 L UMZ 421 series UMZ engine.

In the early 20th century, bigger engines existed, both in road cars and sports cars. Due to the absence of displacement limit regulations, manufacturers took increasing liberties with engine size. In order to achieve power over 100 hp (75 kW), most engine builders simply increased displacement, which could sometimes achieve over 10.0 L. One of the biggest inline-fours of its time was De Dietrich 17,000 cc engine. Its cubic capacity is over twice the size of the Cadillac's 500 CID 8.2 L V8 engine, which was considered the largest engine of its type in the 1970s. These engines ran at very low rpm, often less than 1,500 rpm maximum, and had a specific output of about 10 hp/L. The US tractor industry both farm and industrial relied on large four-cylinder power units until the early 1960s, when six-cylinder designs came into favor. International Harvester built a large 5.7 litre (350 CID) four-cylinder for their WD-9 series tractors.

Other technologically or historically notable engines using this configuration include:

  • Alfa Romeo Twin Cam engine - one of the first mass-produced twin cam engines produced from 1954. Also first engine in production car with variable valve timing.
  • BMC A-Series engine - the first engine to be used in a transverse drive train powering the front wheels of a mass-produced automobile (Mini).
  • Chevrolet Cosworth Twin-Cam Vega - 2.0 L all aluminum (block & head), DOHC, 16 valves, electronic fuel injection, stainless steel header.
  • Dodge A853 - intercooled turbo engine from the SRT-4, set the land speed record for 4-cylinder production cars at the Bonneville Salt Flats.
  • Fiat Twin Cam engine - One of the first mass-produced twincam engines, produced from 1959.
  • Ford Model T engine - one of the most widely produced engines in the world.
  • GM Quad-4 engine - twin-cam Oldsmobile engine offered in GM small, sporty cars.
  • Honda ED engine - first use of Honda's CVCC technology.
  • Honda F20C engine - its 240 horsepower (180 kW) from 2.0 L was the highest specific output of its time, particularly noteworthy in that it achieved this without forced induction.
  • Mitsubishi Sirius engine - includes the 4G63, which has the highest specific output of a turbocharged production engine in the world with the Lancer Evolution FQ-400 available in the United Kingdom (202.9 hp/L)
  • GM Iron Duke engine - A versatile 151 CID 2.5 L 95 horsepower (71 kW) engine used in many GM cars in longitudinal configuration powering rear wheels or a transverse configuration powering front wheels or rear wheels. "Super Duty" racing versions of the Iron Duke were developed by Pontiac Racing.
  • Triumph Slant-4 engine - the first mass-produced multi-valve engine for Triumph and an early turbo engine for Saab.
  • Willys L-134 engine - nicknamed the Go Devil engine. Powered the World War II Jeep and post-war models. Notably undersquare, with 3.125 in (79.4 mm) bore and 4.375 in (111.1 mm) stroke.

In the late 2000s, with auto manufacturers making efforts to increase fuel efficiency and reduce emissions, due to the high price of oil and the economic recession, the proportion of new vehicles with inline-four engines have increased considerably at the expense of V6 and V8 engines. This is particularly evident in mid-size vehicles where a decreasing number of buyers have chosen the V6 performance options.

Racing use

BMW Formula One Engine M12/13, 1500cc turbocharged inline 4

1913 saw a Peugeot driven by Jules Goux winning the Indianapolis 500. This car was powered by an inline-four engine designed by Ernest Henry. This design was very influential for racing engines as it featured for the first time dual overhead camshafts (DOHC) and four valves per cylinder, a layout that would become the standard until today for racing inline-four engines.[16]

This Peugeot was sold to the American driver "Wild Bob" Burman who broke the engine in 1915. As Peugeot couldn't deliver a new engine during World War I, Burman asked Harry Arminius Miller to build a new engine. With John Edward and Fred Offenhauser, Miller created a Peugeot-inspired inline-four engine. This was the first version of the engine that would dominate the Indianapolis 500 until 1976 under the brand Miller and later Offenhauser. The Offenhausers won five straight victories at Indianapolis from 1971 to 1976, and it was not until 1981 that they were eliminated as competitors by engines such as the Cosworth V8 engine.[17]

Many cars produced for the pre-WWII voiturette Grand Prix motor racing category used inline-four engine designs. 1.5 L supercharged engines found their way into cars such as the Maserati 4CL and various English Racing Automobiles (ERA) models. These were resurrected after the war, and formed the foundation of what was later to become Formula One, although the straight-eight supercharged Alfettas would dominate the early years of F1.

Another engine that played an important role in racing history is the inline-four Ferrari engine designed by Aurelio Lampredi. This engine was originally designed as a 2 L Formula 2 engine for the Ferrari 500, but evolved to 2.5 L to compete in Formula One in the Ferrari 625.[18] For sports car racing, capacity was increased up to 3.4 L for the Ferrari 860 Monza.

Yet another very successful engine was the Coventry Climax inline-four originally designed by Walter Hassan as a 1.5 L Formula 2 engine. Enlarged to 2.0 L for Formula One in 1958, it evolved into the large 2495 cc FPF that won the Formula One championship in Cooper's chassis in 1959 and 1960.[19]

In formula One, the 1980s were dominated by the 1500 cc turbocharged cars. The BMW model M12/13 turbo was notable for the era for its high boost pressures and performance. The cast iron block 4-cylinder turbocharged Formula One motor, based on the standard BMW M10 engine introduced in 1961, powered the F1 cars of Brabham, Arrows and Benetton and won the world championship in 1983. In the years 1986 and 1987, the version M12/13/1 was tilted sideways by 72° for use in the extremely low Brabham BT55, unfortunately the design was not successful, probably due to cooling issues in the tight compartment. The 1986 engine was said to produce about 1,300 hp (969 kW) in qualifying.[20]

Motorcycle use

Honda CB750 engine

For racing, Honda built inline-four engines as small as a 125 cc for the Honda 125/4. This engine was replaced by a 125 cc straight-five engine. The largest proprietary inline-four engine in a commercially produced motorcycle is the 1402 cc engine in the Suzuki GSX1400.

Modern inline-four motorcycle engines first gained their popularity with Honda's SOHC CB750 in the 1970s. Since then, the inline-four has become one of the most common engine configurations in street bikes. Outside of the cruiser category, the inline-four is simply the most common configuration because of its relatively high performance-to-cost ratio. All of the Japanese motorcycle manufacturers offer motorcycles with inline-four engines, as does MV Agusta and BMW who employ both longitudinal and transverse-mounted engines. Even the modern Triumph company has offered inline-four-powered motorcycles, though they were discontinued in favour of a triple.

The 2009 Yamaha R1 has an inline-four engine that does not fire at even intervals of 180°. Instead, it uses a crossplane crankshaft that prevents the pistons from simultaneously reaching top dead centre. This results in increased torque at lower engine speeds.

Notes & references

  1. Nunney, Light and Heavy Vehicle Technology, page 12
  2. Nunney, Light and Heavy Vehicle Technology, pp. 13-16
  3. Schembari, James (2010-10-15). "A Family Sedan Firing on Fewer Cylinders - 2010 Buick LaCrosse CX - Review". The New York Times. http://www.nytimes.com/2010/10/17/automobiles/autoreviews/17BUICK.html. 
  4. Ulrich, Lawrence (2010-08-13). "Four-Cylinder Engines Are Smaller, Quieter and Gaining New Respect". The New York Times. http://www.nytimes.com/2010/08/15/automobiles/15FOUR.html. 
  5. http://www.volvopenta.com/volvopenta/na/en-us/marine_leisure_engines/c_diesel_inboard/Pages/d4_300.aspx and http://vppneuapps.volvo.com/ww/PIE/ViewFileFrame.aspx?n=207532&r=2010-06-14-11-34-33&t=PDF1P&a=47701229&p=T416&d=Product%20Bulletins&s=303469&model=D4-300&transClassId=9&segmentId=13&lang=en-US and http://www.bavaria-mallorca.com/power-boats-sport~28-104__en.html
  6. http://www.man-engines.com/datapool/mediapool/800/D0834_LKW_dt.pdf + http://www.mantruckandbus.com/en/Products_and_solutions/MAN_Lkw/TGL/TGL.jsp + http://www.vario-mobil.com/welcome%20to%20variomobil.html + http://en.wikipedia.org/wiki/MAN_Nutzfahrzeuge
  7. http://www.isuzucv.com/engines/4h_index.html + http://www.isuzutruck.co.uk/downloads/specsheets/fseries/f110.210%20easyshift.pdf + http://en.wikipedia.org/wiki/Isuzu_Forward
  8. http://www.hino-global.com/products/diesel_engines/index.html + http://www.hino-global.com/pdf/catalog/Hino_500S_Catalog_LR.pdf + http://en.wikipedia.org/wiki/Hino_Ranger
  9. http://www.scribd.com/doc/17851931/HINO-Series-Catalog + http://www.hino.com.au/Upload/specifications/ranger_pro/FC-SEHi-Grade/Ranger%20Pro%205%20DUMP%20Models.pdf + http://en.wikipedia.org/wiki/Hino_Ranger
  10. http://www.farmtrader.co.nz/View/Article/Kubota-M135X-tractor/2234.aspx + http://www.kubota.com/product/M100X/M100X.aspx + http://www.kubota.com/f/aboutkubota/prl80.cfm
  11. "A comprehensive A-Z listing of marine diesel engines in excess of 300kW". http://www.masson-marine.com/fic_bdd/annexe_pdf_fichier_fr/12436415290_MARINE_DIESEL_ENGINE_DATABASE_FROM_MOTORSHIP.pdf. Retrieved 2011-11-13. 
  12. Nunney, 14-15
  13. Nunney, 42-44
  14. Nunney, 40-44.
  15. "D0834_LKW_dt.indd" (PDF). http://www.man-engines.com/datapool/mediapool/800/D0834_LKW_dt.pdf. Retrieved 2011-08-01. 
  16. Ludvigsen, Classic Racing Engines,pages 14–17
  17. Ludvigsen, 182-185.
  18. Ludvigsen, 78-81, 86-89.
  19. Ludvigsen, 130-133.
  20. "BMW Turbo F1 Engine". Gurneyflap.com. http://www.gurneyflap.com/bmwturbof1engine.html. Retrieved 2010-09-13. 
  • Ludvigsen, Karl (2001). Classic Racing Engines. Haynes Publishing. ISBN 1-85960-649-0. 
  • Nunney, M J (2006). Light and Heavy Vehicle Technology (4th ed.). Butterworth-Heinemann. ISBN 0-7506-8037-7. 
</dl>
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