A multi-step reaction model for ignition of fully-dense Al-CuO nanocomposite powders

Document Type

Article

Publication Date

12-1-2012

Abstract

A multi-step reaction model is developed to describe heterogeneous processes occurring upon heating of an Al-CuO nanocomposite material prepared by arrested reactive milling. The reaction model couples a previously derived Cabrera-Mott oxidation mechanism describing initial, low temperature processes and an aluminium oxidation model including formation of different alumina polymorphs at increased film thicknesses and higher temperatures. The reaction model is tuned using traces measured by differential scanning calorimetry. Ignition is studied for thin powder layers and individual particles using respectively the heated filament (heating rates of 103-104 K s-1) and laser ignition (heating rate ~106 K s-1) experiments. The developed heterogeneous reaction model predicts a sharp temperature increase, which can be associated with ignition when the laser power approaches the experimental ignition threshold. In experiments, particles ignited by the laser beam are observed to explode, indicating a substantial gas release accompanying ignition. For the heated filament experiments, the model predicts exothermic reactions at the temperatures, at which ignition is observed experimentally; however, strong thermal contact between the metal filament and powder prevents the model from predicting the thermal runaway. It is suggested that oxygen gas release from decomposing CuO, as observed from particles exploding upon ignition in the laser beam, disrupts the thermal contact of the powder and filament; this phenomenon must be included in the filament ignition model to enable prediction of the temperature runaway. © 2012 Copyright Taylor and Francis Group, LLC.

Identifier

84870860163 (Scopus)

Publication Title

Combustion Theory and Modelling

External Full Text Location

https://doi.org/10.1080/13647830.2012.694480

e-ISSN

17413559

ISSN

13647830

First Page

1011

Last Page

1028

Issue

6

Volume

16

Fund Ref

Defense Threat Reduction Agency

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