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Detonation


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For other uses, see Detonation (disambiguation)
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Detonation of the 500-ton TNT explosive charge as part of Operation Sailor
Hat . The blast wave is visible on the water surface and a shock
condensation cloud is visible overhead.

*Detonation* involves an exothermic front accelerating through a medium
that eventually drives a shock front propagating directly in front of it.
They are observed in both conventional solid and liquid explosives,^[1] as
well as in reactive gases. The velocity of detonations in solid and liquid
explosives is much higher than that in gaseous ones, which allows far
clearer resolution of the wave system in the latter.

Gaseous detonations normally occur in confined systems but are
occasionally observed in large vapor clouds. Again, they are often
associated with a gaseous mixture of fuel and oxidant of a composition,
somewhat below conventional flammability limits. There is an extraordinary
variety of fuels that may be present as gases, as droplet fogs and as dust
suspensions. Other materials, such as acetylene, ozone and hydrogen
peroxide are detonable in the absence of oxygen, fuller lists are given by
both Stull^[2] and Bretherick^[3] . Oxidants include halogens, ozone,
hydrogen peroxide and oxides of nitrogen and chlorine.

In terms of external damage, it is important to distinguish between
detonations and deflagrations where the exothermic wave is subsonic and
maximum pressures are at most a quarter^[/citation needed /] of those
generated by the former. Processes involved in the transition between
deflagration and detonation are covered thoroughly by Nettleton.^[4]


Contents

[hide ]

* 1 Etymology * 2 Theories * 3 Applications * 4 See also * 5 References *
6 External Links


[edit ] Etymology

Search Wiktionary
	Look up /*detonation */ in Wiktionary , the free dictionary.

French /détoner/, *to explode*; from Latin /detonare/, *to expend
thunder*; from /de-/, ~*off* + /tonare/, *to thunder*


[edit ] Theories

The simplest theory to predict the behavior of detonations in gases is
known as Chapman-Jouguet (CJ) theory, developed around the turn of the
20th century. This theory, described by a relatively simple set of
algebraic equations, models the detonation as a propagating shock wave
accompanied by exothermic heat release. Such a theory confines the
chemistry and diffusive transport processes to an infinitely thin zone.

A more complex theory was advanced during World War II independently by
Zel'dovich , von Neumann , and W. Doering .^[5] ^[6] ^[7] This theory, now
known as ZND theory , admits finite-rate chemical reactions and thus
describes a detonation as an infinitely thin shock wave followed by a zone
of exothermic chemical reaction. With a reference frame of a stationary
shock, the following flow is subsonic, so that an acoustic reaction zone
follows immediately behind the lead front, the Chapman-Jouguet condition
.^[8] ^[9]

Both theories describe one-dimensional and steady wave fronts. However, in
the 1960s, experiments revealed that gas-phase detonations were most often
characterized by unsteady, three-dimensional structures, which can only in
an averaged sense be predicted by one-dimensional steady theories. Indeed,
such waves are quenched as their structure is destroyed.^[10] ^[11]

Experimental studies have revealed some of the conditions needed for the
propagation of such fronts. In confinement, the range of composition of
mixes of fuel and oxidant and self-decomposing substances with inerts are
slightly below the flammability limits and for spherically expanding
fronts well below them.^[12] The influence of increasing the concentration
of diluent on expanding individual detonation cells has been elegantly
demonstrated.^[13] Similarly their size grows as the initial pressure
falls.^[14] Since cell widths must be matched with minimum dimension of
containment, any wave overdriven by the initiator will be quenched.

Mathematical modeling has steadily advanced to predicting the complex flow
fields behind shocks inducing reactions.^[15] ^[16] To date none has
adequately described how structure is formed and sustained behind
unconfined waves.


[edit ] Applications



A pulsed detonation engine ground demonstrator operating at a frequency of
35 Hz (35 detonation waves per second). Fuel and oxidizer are supplied to
the engine using a valving system that matches with the operating
frequency.

The main cause of damage from explosive devices is due to a supersonic
blast front (a powerful shock wave ) in the surrounding area. Therefore,
the detonation is primarily associated with explosives and the
acceleration of various projectiles. However, detonation waves may also be
utilized for less-destructive purposes like deposition of coatings to a
surface^[17] or cleaning of equipment (i.e., slag removal^[18] ). Pulse
detonation engines utilize the detonation wave for aerospace
propulsion.^[19] The first flight of an aircraft powered by a pulse
detonation engine took place at the Mojave Air & Space Port on January 31,
2008.^[20]


[edit ] See also

* Carbon detonation * Detonator * Explosive#Detonation of an explosive
charge

* Detonation diamond * Detonation flame arrester * Sympathetic detonation
* Nuclear testing * Nuclear chain reaction#Predetonation

* Chapman-Jouguet condition * Engine knocking


[edit ] References

1. *^ * Fickett and Davis, 'Detonation', Univ. California Press, (1979).
2. *^ * Stull, Fundamentals of fire and explosion, A.I.Chem.E., Monograph
Series 10,73 (1977) 3. *^ * Bretherick, 'Handbook of Reactive Chemical
Hazards, Butterworths, London, (1979) 4. *^ * Nettleton, 'Gaseous
Detonations: Their Nature, Effects and Control', Butterworths, London,
(1987). 5. *^ * Zel'dovich and Kompaneets, 'Theory of Detonation',
Academic Press, New York, (1960). 6. *^ * von Neumann, Progress report on
the theory of detonation waves, OSRD Report No. 549. 7. *^ * Doring,
Ann.Physik, 43,421, (1943). 8. *^ * Chapman, Phil.Mag.,47,90, (1899). 9.
*^ * Jouguet, J.Maths Pure Appl.,7,347, (1905). 10. *^ * Edwards, D.H.,
Thomas, G.O., and Nettleton, M.A., "The Diffraction of a Planar Detonation
Wave at an Abrupt Area Change," /Journal of Fluid Mechanics/, Vol. 95, No.
1, pp. 79-96, 1979. 11. *^ * Edwards, Nettleton and Thomas, 'Gas Dynamics
of Detonations and Explosions', Vol.75 of Prog. in Astro. and Aero.,
(1981). 12. *^ * Nettleton, Fire Prev.Sci.and Tech., No23,29, (1980). 13.
*^ * Munday, G., Ubbelohde, A.R., and Wood, I.F., "Fluctuating Detonation
in Gases," /Proceedings of the Royal Society A/, Vol. 306, pp. 171-178,
1968. 14. *^ * Barthel, H.O., "Predicted Spacings in Hydrogen-Oxygen-Argon
Detonations," /Physics of Fluids/, Vol. 17, No. 8, pp. 1547-1553, 1974.
15. *^ * Oran and Boris, 'Numerical Simulation of Reactive Flows',
Elsevier Publishers, (1987) 16. *^ * Sharpe, G.J., and Quirk, J.J.,
"Nonlinear cellular dynamics of the idealized detonation model: Regular
cells," /Combustion Theory and Modelling/, Vol. 12, No. 1, pp. 1-21, 2008.
17. *^ * Nikolaev, Yu.A., Vasil'ev, A.A., and Ul'yanitskii, B.Yu., "Gas
Detonation and it's Application in Engineering and Technologies (Review),
/Combustion, Explosion, and Shock Waves/, Vol. 39, No. 4, pp. 382-410,
2003. 18. *^ * Huque, Z., Ali, M.R., and Kommalapati, R., "Application of
pulse detonation technology for boiler slag removal," /Fuel Processing
Technology/, Vol. 90, No. 4, pp. 558-569, 2009. 19. *^ * Kailasanath, K.,
"Review of Propulsion Applications of Detonation Waves," /AIAA Journal/,
Vol. 39, No. 9, pp. 1698-1708, 2000. 20. *^ * Norris, G., "Pulse Power:
Pulse Detonation Engine-powered Flight Demonstration Marks Milestone in
Mojave," /Aviation Week & Space Technology/, Vol. 168, No. 7, pp. 60,
2008.