Turbocharger

From AviationSafetyX Wiki
Jump to navigation Jump to search

<templatestyles src="Module:Hatnote/styles.css"></templatestyles>

"Turbo" redirects here. For other uses, see Turbo (disambiguation).

Cut-away view turbocharger (turbine section on the left, compressor section on the right)

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.[1][2]

Turbochargers are distinguished from superchargers in that 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).[3] However, up until the mid-20th century, a turbocharger was called a "turbosupercharger" and was considered a type of supercharger.[4]

History[edit | edit source]

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 a design by Scottish engineer Dugald Clerk.[5] Then in 1885, Gottlieb Daimler patented the technique of using a gear-driven pump to force air into an internal combustion engine.[6]

The 1905 patent by Alfred Büchi, a Swiss engineer working at Sulzer is often considered the birth of the turbocharger.[7][8][9] This patent was for a compound radial engine with an exhaust-driven axial flow turbine and compressor mounted on a common shaft.[10][11] 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.[12][13] However, the prototype was not reliable and did not reach production.[12] Another early patent for turbochargers was applied for in 1916 by French steam turbine inventor Auguste Rateau, for their intended use on the Renault engines used by French fighter planes.[10][14] 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.[10] The testing was conducted at Pikes Peak in the United States using the Liberty L-12 aircraft engine.[14]

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.[15] This was followed very closely in 1925, when Alfred Büchi successfully installed turbochargers on ten-cylinder diesel engines, increasing the power output from 1,300 to 1,860 kilowatts (1,750 to 2,500 hp).[16][17][18] This engine was used by the German Ministry of Transport for two large passenger ships called the Preussen and Template:Ship. The design was licensed to several manufacturers and turbochargers began to be used in marine, railcar and large stationary applications.[13]

Turbochargers were used on several aircraft engines during World War II, beginning with the Boeing B-17 Flying Fortress in 1938, which used turbochargers produced by General Electric.[10][19] 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.[20] The Swiss industry played a pioneering role with turbocharging engines as witnessed by Sulzer, Saurer and Brown, Boveri & Cie.[21][22]

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.[8][13] The first turbocharged cars were the short-lived Chevrolet Corvair Monza and the Oldsmobile Jetfire, both introduced in 1962.[23][24]

The turbo succeeded in motorsport, but took its time. The 1968 Indianapolis 500 was the first to be won with a turbocharged engine, turbos winning on the fast oval track ever since. On twisty road race tracks, Porsche pioneered turbos in engines derived from the 1963 Porsche 911 which had an air-cooled flat six engine, just like the Chevrolet Corvair, but got turbocharged ten years later. Porsche 935 and Porsche 936 won both kinds of Sportcars World Championships in 1976, as well as the Le Mans 24h, proving that they can be reliable and fast. In Formula One, capacity was limited to only 1.5 litre, with the first race victories coming in the late 1970s, and the first F1 World Championship in 1983, with a BMW M10-based 4-cylinder engine that dates back to 1961.

Turbodiesel passenger cars appeared in the 1970s, with the Mercedes 300 D. Greater adoption of turbocharging in passenger cars began in the 1980s, as a way to increase the performance of smaller displacement engines.[10]

Design[edit | edit source]

Turbocharger components

Like other forced induction devices, a compressor in the turbocharger pressurises the intake air before it enters the inlet manifold.[25] 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.[26][27]

The main components of the turbocharger are:

Turbine[edit | edit source]

Turbine section of a Garrett GT30 with the turbine housing removed

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 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.[28][29] Some turbocharger designs are available with multiple turbine housing options, allowing a housing to be selected to best suit the engine's characteristics and the performance requirements.

A turbocharger's performance is closely tied to its size,[30] 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 a limiting factor in the peak power produced by the engine.[31][32] 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.[33]

Twin-scroll[edit | edit source]

A twin-scroll turbocharger uses two separate exhaust gas inlets, to make use of the pulses in the flow of the exhaust gasses from each cylinder.[34] 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 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.[35][36]

Another common feature of twin-scroll turbochargers 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.[37]

  • Cutaway view showing the two scrolls of a Mitsubishi twin-scroll (the larger scroll is illuminated in red)
    Cutaway view showing the two scrolls of a Mitsubishi twin-scroll (the larger scroll is illuminated in red)
  • Transparent exhaust manifold and turbo scrolls on a Hyundai Gamma engine, showing the paired cylinders (1 & 4 and 2 & 3)
    Transparent exhaust manifold and turbo scrolls on a Hyundai Gamma engine, showing the paired cylinders (1 & 4 and 2 & 3)

Variable-geometry[edit | edit source]

Cutaway view of a Porsche variable-geometry turbocharger

<templatestyles src="Module:Hatnote/styles.css"></templatestyles>

Main article: Variable-geometry turbocharger

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 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,[38] 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 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.[30][31] The benefit of variable-geometry turbochargers is that the optimum aspect ratio at low engine speeds is very different from that at high engine speeds.

Electrically-assisted turbochargers[edit | edit source]

An electrically-assisted turbocharger combines a traditional exhaust-powered turbine with an electric motor, in order to reduce turbo lag. Recent advancements in electric turbocharger technology,[when?] such as mild hybrid integration,[39] have enabled turbochargers to start spooling before exhaust gases provide adequate pressure. This can further reduce turbo lag[40] and improve engine efficiency, especially during low-speed driving and frequent stop-and-go conditions seen in urban areas. This differs from an electric supercharger, which solely uses an electric motor to power the compressor.

Compressor[edit | edit source]

Compressor section of a Garrett GT30 with the compressor housing removed

The compressor draws in outside air through 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.

Ported shroud[edit | edit source]

Some turbochargers use a "ported shroud", whereby a ring of holes or circular grooves allows air to bleed around the compressor blades. Ported shroud designs can have greater resistance to compressor surge and can improve the efficiency of the compressor wheel.[41][42]

Center hub rotating assembly[edit | edit source]

The center hub rotating assembly (CHRA) houses the shaft that connects the turbine to the compressor. A lighter shaft can help reduce turbo lag.[43] 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 the engine's coolant to flow through. One reason for water cooling is to protect the turbocharger's lubricating oil from overheating.

Supporting components[edit | edit source]

Schematic of a typical turbo petrol engine

The simplest type of turbocharger is the free floating turbocharger.[44] 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.[44]

Additional components that are commonly used in conjunction with turbochargers are:

  • Intercooler - a radiator used to cool the intake air after it has been pressurised by the turbocharger[45]
  • Water injection - spraying water into the combustion chamber, in order to cool the intake air[46]
  • Wastegate - many turbochargers are capable of producing boost pressures in some circumstances that are higher than the engine can safely withstand, therefore a wastegate is often used to limit the amount of exhaust gases that enters the turbine
  • Blowoff valve - to prevent compressor stall when the throttle is closed

Turbo lag and boost threshold [edit | edit source]

Template:Refimprove section

Turbo lag refers to delay – when 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.[47][48] 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.[49] The effect of turbo lag is reduced throttle response, in the form of a delay in the power delivery.[50] Superchargers do not suffer from turbo lag because the compressor mechanism is driven directly by the engine.

Methods to reduce turbo lag include:[citation needed]

  • Lowering the rotational inertia of the turbocharger by using lower radius parts and ceramic and other lighter materials
  • Changing the turbine's aspect ratio (A/R ratio)
  • Increasing upper-deck air pressure (compressor discharge) and improving wastegate response
  • Reducing bearing frictional losses, e.g., using a foil bearing rather than a conventional oil bearing
  • Using variable-nozzle or twin-scroll turbochargers
  • Decreasing the volume of the upper-deck piping
  • Using multiple turbochargers sequentially or in parallel
  • Using an antilag system
  • Using a turbocharger spool valve to increase exhaust gas flow speed to the (twin-scroll) turbine
  • Using a butterfly valve to force exhaust gas through a smaller passage in the turbo inlet
  • Electric turbochargers[51] and hybrid turbochargers.

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 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.

Use of multiple turbochargers[edit | edit source]

<templatestyles src="Module:Hatnote/styles.css"></templatestyles>

Main article: Twin-turbo

Some engines use multiple turbochargers, usually to reduce turbo lag, increase 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.

Turbocharging versus supercharging[edit | edit source]

<templatestyles src="Module:Hatnote/styles.css"></templatestyles>

Main article: Supercharger #Supercharging versus turbocharging

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 the crankshaft) whereas a turbocharger is powered by the kinetic energy of the engine's exhaust gas.[52] A turbocharger does not place a direct mechanical load on the engine, although turbochargers place exhaust back pressure on engines, increasing pumping losses.[52]

Supercharged engines are common in applications where throttle response is a key concern, and supercharged engines are less likely to heat soak the intake air.

Twincharging[edit | edit source]

<templatestyles src="Module:Hatnote/styles.css"></templatestyles>

Main article: Twincharger

A combination of an exhaust-driven turbocharger and an engine-driven supercharger can mitigate the weaknesses of both.[53] This technique is called twincharging.

Applications[edit | edit source]

A medium-sized six-cylinder marine diesel-engine, with turbocharger and exhaust in the foreground

Turbochargers have been used in the following applications:

In 2017, 27% of vehicles sold in the US were turbocharged.[55] In Europe 67% of all vehicles were turbocharged in 2014.[56] Historically, more than 90% of turbochargers were diesel, however, adoption in petrol engines is increasing.[57] The companies which manufacture the most turbochargers in Europe and the U.S. are Garrett Motion (formerly Honeywell), BorgWarner and Mitsubishi Turbocharger.[2][58][59]

Safety[edit | edit source]

Turbocharger failures and resultant high exhaust temperatures are among the causes of car fires.[60]

Failure of the seals will cause oil to leak into the exhaust system causing blue-gray smoke or a runaway diesel.

See also[edit | edit source]

<templatestyles src="Module:Side box/styles.css"></templatestyles><templatestyles src="Sister project/styles.css"></templatestyles>

<templatestyles src="Plainlist/styles.css"></templatestyles>
Wikimedia Commons has media related to Turbochargers.Template:Preview warning

References[edit | edit source]


Template:Automotive engine

  1. How Turbochargers Work.  Karim Nice.  (4 December 2000)  Auto.howstuffworks.com.  Retrieved 1 June 2012 from link
  2. 2.0 2.1 [1] Archived 26 March 2011 at the Wayback Machine
  4. The Turbosupercharger and the Airplane Power Plant.  (1943-12-30)  Rwebs.net.  Retrieved 2010-08-03 from link
  6. History of the Supercharger.  Retrieved 30 June 2011 from link
  7. Celebrating 110 years of turbocharging.  ABB.  Retrieved 22 July 2021 from link
  8. 8.0 8.1 The turbocharger turns 100 years old this week.  (18 November 2005)  Retrieved 20 September 2019 from www.newatlas.com
  10. 10.0 10.1 10.2 10.3 10.4
  11. Template:Patent
  12. 12.0 12.1 Alfred Büchi the inventor of the turbocharger - page 1.  Retrieved from www.ae-plus.com
  13. 13.0 13.1 13.2 Turbocharger History.  Retrieved 20 September 2019 from www.cummins.ru
  14. 14.0 14.1
  16. Alfred Büchi the inventor of the turbocharger - page 2.  Retrieved from www.ae-plus.com
  17. Compressor Performance: Aerodynamics for the User. M. Theodore Gresh. Newnes, 29 March 2001
  18. Diesel and gas turbine progress, Volume 26. Diesel Engines, 1960
  19. World War II - General Electric Turbosupercharges.  Retrieved from aviationshoppe.com [dead link]Template:Cbignore
  20. Saurer Geschichte.  Retrieved from link
  21. Ernst Jenny: "Der BBC-Turbolader." Birkhäuser, Basel, 1993, ISBN 978-3-7643-2719-4. "Buchbesprechung." Neue Zürcher Zeitung, May 26, 1993, p. 69.
  22. Template:Patent, issued 1989-07-13, assigned to BBC Brown Boveri AG, Baden, Switzerland
  24. History.  Retrieved 20 September 2019 from www.bwauto.com
  25. Variable-Geometry Turbochargers.  (24 October 2010)  Large.stanford.edu.  Retrieved 1 June 2012 from link
  26. Happy 100th Birthday to the Turbocharger - News - Automobile Magazine.  (21 December 2005)  Retrieved 25 June 2022 from www.MotorTrend.com
  27. How Turbo Chargers Work.  Conceptengine.tripod.com.  Retrieved 1 June 2012 from link
  28. Mechanical engineering: Volume 106, Issues 7-12; p.51
  29. Popular Science. Detroit's big switch to Turbo Power. Apr 1984.
  30. 30.0 30.1 Variable-Geometry Turbochargers.  Thomas Veltman.  (24 October 2010)  Coursework for Physics 240.  Retrieved 17 April 2012 from link
  31. 31.0 31.1 How does Variable Turbine Geometry work?.  Paul Tan.  (16 August 2006)  PaulTan.com.  Retrieved 17 April 2012 from link
  32. A National Maritime Academy Presentation. Variable Turbine Geometry.
  34. Twin-Turbocharging: How Does It Work?.  (11 October 2016)  Retrieved 16 June 2022 from www.CarThrottle.com
  35. A Look At Twin Scroll Turbo System Design - Divide And Conquer?.  (20 May 2009)  Retrieved 16 June 2022 from www.MotorTrend.com
  36. Twin Scroll Turbo System Design.  David Pratte.  Modified Magazine.  Retrieved 28 September 2012 from link
  37. BorgWarner's Twin Scroll Turbocharger Delivers Power and Response for Premium Manufacturers - BorgWarner.  Retrieved 16 June 2022 from www.borgwarner.com
  39. What is an electric turbocharger?.  (2018-07-04)  Retrieved 2024-12-10 from Mitsubishi Turbocharger
  40. Truett, Richard, and Jens Meiners. “Electric Turbocharger Eliminates Lag, Valeo Says.” Automotive News, vol. 88, no. 6632, p. 34.
  41. Ported Shroud Conversions.  Retrieved 18 June 2022 from www.turbodynamics.co.uk
  42. GTW3684R.  Retrieved 18 June 2022 from www.GarrettMotion.com
  44. 44.0 44.1 How Turbocharged Piston Engines Work.  TurboKart.com.  Retrieved 17 April 2012 from link
  45. How a Turbocharger Works.  Retrieved 25 June 2022 from www.GarrettMotion.com
  46. Get Schooled: Water Methanol Injection 101.  Mark Gearhart.  (22 July 2011)  Retrieved from Dragzine
  47. What Is Turbo Lag? And How Do You Get Rid Of It?.  (7 March 2015)  Retrieved 12 June 2022 from www.MotorTrend.com
  48. Turbo Lag. Reasons For Turbocharger Lag. How To Fix Turbo Lag.  (25 September 2021)  Retrieved 12 June 2022 from www.CarBuzz.com
  49. What is turbo lag?.  Retrieved 12 June 2022 from www.enginebasics.com
  50. 5 Ways To Reduce Turbo Lag.  (19 July 2016)  Retrieved 12 June 2022 from www.CarThrottle.com
  51. Turbochargers: an interview with Garrett's Martin Verschoor.  Terry Parkhurst.  (10 November 2006)  Allpar.  Retrieved 12 December 2006 from link
  52. 52.0 52.1 What is the difference between a turbocharger and a supercharger on a car's engine?.  (1 April 2000)  Retrieved 1 June 2012 from HowStuffWorks
  53. How to twincharge an engine.  (29 March 2012)  Torquecars.com.  Retrieved 1 June 2012 from link
  54. BorgWarner turbo history.  Turbodriven.com.  Retrieved 2 August 2010 from link
  55. Turbo Engine Use at Record High.  (7 August 2017)  Retrieved 22 July 2021 from link
  56. Honeywell sees hot turbo growth ahead.  (7 January 2015)  Retrieved 19 May 2017 from Automotive News
  58. IHI Aims to Double Turbocharger Sales by 2013 on Europe Demand.  Makiko Kitamura.  (24 July 2008)  Bloomberg.  Retrieved 1 June 2012 from link
  59. Turbochargers - European growth driven by spread to small cars.  (18 November 2002)  Just-auto.com.  Retrieved 1 June 2012 from link
  60. Why trucks catch fire. Australian Road Transport Suppliers Association (ARTSA). November 2006. Retrieved 2020-07-22.
Retrieved from "https://wiki.alsresume.com/index.php?title=Turbocharger&oldid=7645"