There are five necessary conditions for a dust explosion: • A combustible
dust • The dust is dispersed in the air within certain
flammability limits • There is an
oxidant (typically atmospheric oxygen) • There is an ignition source • The area is confineda building can be an enclosure
Sources of dust rendering of the
Great Mill Disaster in
Australia 1921. These cable drums were blown 50 feet (15 m) from their foundations following a
coal dust explosion. in
Port Wentworth, Georgia, US Many common materials which are known to burn can generate a dust explosion, such as
coal dust and
sawdust. In addition, many otherwise mundane organic materials can also be dispersed into a dangerous dust cloud, such as
grain,
flour,
starch,
sugar,
powdered milk,
cocoa,
coffee, and
pollen.
Powdered metals (such as
aluminum,
magnesium, and
titanium) can form explosive suspensions in air, if finely divided. A
gigantic explosion of flour dust destroyed a mill in Minnesota on May 2, 1878, killing 14 workers at the
Washburn A Mill and another four in adjacent buildings. A similar problem occurs in
sawmills and other places dedicated to
woodworking. Since the advent of industrial production–scale
metal powder–based
additive manufacturing (AM) in the 2010s, there is growing need for more information and experience with preventing dust explosions and
fires from the traces of excess
metal powder sometimes left over after laser
sintering or other fusion methods. For example, in
machining operations downstream of the AM build, excess powder liberated from porosities in the support structures can be exposed to sparks from the cutting interface. are two common means of producing safe, controlled fire effects. To support rapid combustion, the dust must consist of very small particles with a high
surface area to volume ratio, thereby making the collective or combined surface area of all the particles very large in comparison to a dust of larger particles.
Dust is defined as
powders with particles less than about 500 micrometres in diameter, but
finer dust will present a much greater hazard than coarse particles by virtue of the larger total surface area of all the particles.
Concentration Below a certain value, the
lower explosive limit (LEL), there is insufficient dust to support the combustion at the rate required for an explosion. Similarly, if the
fuel to air ratio increases above the
upper explosive limit (UEL), there is insufficient oxidant to permit combustion to continue at the necessary rate. Determining the minimum explosive concentration or maximum explosive concentration of dusts in air is difficult, and consulting different sources can lead to quite different results. Typical explosive ranges in air are from few dozens grams/m3 for the minimum limit, to few kg/m3 for the maximum limit. For example, the LEL for sawdust has been determined to be between 40 and 50 grams/m3. It depends on many factors including the type of material used.
Oxidant Typically, normal atmospheric oxygen can be sufficient to support a dust explosion if the other necessary conditions are also present. High-oxygen or pure oxygen environments are considered to be especially hazardous, as are strong oxidizing gases such as
chlorine and
fluorine. Also, particulate suspensions of compounds with a high oxidative potential, such as
peroxides,
chlorates,
nitrates,
perchlorates, and
dichromates, can increase risk of an explosion if combustible materials are also present.
Sources of ignition There are many sources of ignition, and a naked flame need not be the only one: over one half of the dust explosions in Germany in 2005 were from non-flame sources. Common sources of ignition include: •
electrostatic discharge (e.g. an improperly installed
conveyor belt, which can act like a
Van de Graaff generator) •
friction •
electrical arcing from machinery or other equipment • hot surfaces (e.g. overheated
bearings) •
fire • self-ignition However, it is often difficult to determine the exact source of ignition when investigating after an explosion. When a source cannot be found, ignition will often be attributed to
static electricity. Static charges can be generated by external sources, or can be internally generated by friction at the surfaces of particles themselves as they collide or move past one another. == Mechanism ==