Diesel engine runaway explained

Diesel engine runaway is an occurrence in diesel engines, in which the engine draws extra fuel from an unintended source and overspeeds at higher and higher RPM, producing up to ten times the engine's rated output until destroyed by mechanical failure or bearing seizure due to a lack of lubrication.[1] Hot-bulb engines and jet engines can also run away via the same process.

Causes

In a diesel engine, the torque and the rotational speed are controlled by means of quality torque manipulation. This means that, with each intake stroke, the engine draws in air which is not mixed with fuel; the fuel is injected into the cylinder after its contents have been compressed during the compression stroke. The high air temperature near the end of the compression stroke causes spontaneous combustion of the mixture as the fuel is injected. The output torque is controlled by adjusting the mass of injected fuel; the more fuel injected, the higher the torque produced. Adjusting the amount of fuel received per stroke alters the quality of the air-fuel-mixture, and adjusting the amount of the mixture itself is not required, negating the need for a throttle valve.[2] [3]

Diesel engines can combust a large variety of fuels, including many sorts of oil, petrol,[4] and combustible gases.[5] This means that if there is any type of leak or malfunction that increases the amount of oil or fuel unintentionally entering the combustion chamber, the quality of the air-fuel-mixture will increase, causing torque and rotational speed to increase.

Fuel and oil leaks causing engine runaways can have both internal and external causes. Broken seals or a broken turbocharger may cause large amounts of oil mist to enter the inlet manifold, whereas defective injection pumps may cause an unintentionally large amount of fuel to be injected directly into the combustion chamber. If a diesel engine is operated in an environment where combustible gases are used, a gas leak may result in an engine runaway if the gas can enter the engine's inlet manifold.[6]

Stopping a runaway engine

Several ways to stop a runaway diesel engine are to block off the air intake, either physically using a cover or plug, or alternatively by directing a fire extinguisher into the air intake to smother the engine.[7] Engines fitted with a decompressor can also be stopped by operating the decompressor, and in a vehicle with a manual transmission it is sometimes possible to stop the engine by engaging a high gear (i.e. 4th, 5th, 6th etc.), with foot brake and parking brake fully applied, and quickly letting out the clutch to slow the engine RPM to a stop, without moving the vehicle. This should be the last option because it can result in catastrophic damage to the whole transmission, mainly the gearbox, but this operation can save the engine.

Notable incidents involving diesel engine runaway

In the Texas City refinery explosion, an instance of diesel engine runaway is thought to have provided the ignition source that triggered the massive explosion. After the refinery's blowdown stack failed and started releasing raffinate into the air, a pickup truck that had been parked near the blowdown stack with its engine idling was engulfed by the vapor cloud released and the engine began to race. As staff at the refinery attempted to stop the truck's now-overheating engine, it backfired, igniting the vapor cloud and triggering the disaster.[8]

Bibliography

See also

External links

Notes and References

  1. Book: Wellington, B.F. . Alan F. Asmus . Diesel Engines and Fuel Systems . . 1995 . 0-582-90987-2 . registration .
  2. Stefan Pischinger, Ulrich Seiffert (ed.): Vieweg Handbuch Kraftfahrzeugtechnik. 8th edition, Springer, Wiesbaden 2016. . p. 348.
  3. Morton Lippmann (ed.): Environmental Toxicants – Human Exposures and Their Health Effects, 3rd edition, Wiley, Hoboken 2009, . p. 553: ″Because the air entering diesel engines is not throttled, the engines can operate at air–fuel ratios other than that required for stoichiometric combustion. Fuel is injected under pressure into the combustion chamber in variable amounts to achieve different engine speeds and power outputs.″
  4. Hans Christian Graf von Seherr-Thoß (auth): Die Technik des MAN Nutzfahrzeugbaus, in MAN Nutzfahrzeuge AG (ed.): Leistung und Weg: Zur Geschichte des MAN Nutzfahrzeugbaus, Springer, Berlin/Heidelberg, 1991. . p. 436
  5. Richard van Basshuysen (ed.): Erdgas und erneuerbares Methan für den Fahrzeugantrieb in H. List: Der Fahrzeugantrieb, Springer, Wiesbaden 2015,, p. 418
  6. Donald Launer: Lessons from My Good Old Boat, Sheridan House, Inc., 2007,, p. 161
  7. Book: Launer, Donald . William G. Seifert . Daniel Spurr . Lessons from My Good Old Boat . Sheridan House, Inc. . 2007 . 161–162. 978-1-57409-250-9.
  8. U.S. Chemical Safety and Hazard Investigation Board. Investigation Report - Refinery Fire and Explosion and Fire. BP Texas City March 23, 2005, para 2.5.13 Ignition Source, p66