Piston Engine Combustion
Flying|December 2017

ALL ABOUT DETONATION, PRE-IGNITION AND BACKFIRING

Richie Lengel
Piston Engine Combustion

RELEVANT DISCUSSION:

FAA-H-8083-25, 8083-30, 8083- 31, 8083-32, AC 33.28-2, AC 33.28-3, AC 33.47-1, AC 65-12, AC 91-33, FAA-P-8740-35

Not so many years ago, before computers got involved, automobile engines ran using all sorts of ancient technology that made them prone to detonation and/or pre-ignition when the timing and fuel mixture got out of whack. These symptoms, usually called “engine knock,” were quite common and relatively easy to detect at automobile speeds, but not so easy to detect at airplane speeds and noise levels. Of course, the majority of the general aviation fleet still relies on some of that same ancient technology and even throws in some parts from a farm tractor (magnetos). Here’s a primer on how these conditions relate to aircraft engines.

NORMAL COMBUSTION: Occurs when the fuel/air mixture ignites in the cylinder and burns progressively at a fairly uniform rate across the combustion chamber. When ignition is properly timed, maximum pressure is built up just after the piston has passed top dead center at the end of the compression stroke. The flame fronts start at each spark plug and burn in more or less wavelike forms. The velocity of the flame travel is influenced by the type of fuel, the ratio of the fuel/air mixture and the pressure and temperature of the fuel mixture.

Diese Geschichte stammt aus der December 2017-Ausgabe von Flying.

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Diese Geschichte stammt aus der December 2017-Ausgabe von Flying.

Starten Sie Ihre 7-tägige kostenlose Testversion von Magzter GOLD, um auf Tausende kuratierte Premium-Storys sowie über 8.000 Zeitschriften und Zeitungen zuzugreifen.