On the Mechanism of Detonation Combustion of Nanostructured Silicon with a Solid-Phase Oxidant

The physical mechanism of detonation combustion of nanostructured silicon with a solid-phase oxidant at a velocity of the combustion front of 1000–3000 m/s has been proposed. Thermodynamic characteristics of combustion of model solid-phase mixtures “silicon–ammonium perchlorate” with different equiv...

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Veröffentlicht in:	Journal of engineering physics and thermophysics 2020-11, Vol.93 (6), p.1439-1448
Hauptverfasser:	Krivosheyev, P. N., Mironov, V. N., Penyazkov, O. G., Futko, S. I.
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Classical Mechanics Combustion Complex Systems Engineering Engineering Thermodynamics Heat and Mass Transfer Heat and Mass Transfer in Combustion Processes Industrial Chemistry/Chemical Engineering Silicon Thermodynamics
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container_end_page	1448
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container_title	Journal of engineering physics and thermophysics
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creator	Krivosheyev, P. N. Mironov, V. N. Penyazkov, O. G. Futko, S. I.
description	The physical mechanism of detonation combustion of nanostructured silicon with a solid-phase oxidant at a velocity of the combustion front of 1000–3000 m/s has been proposed. Thermodynamic characteristics of combustion of model solid-phase mixtures “silicon–ammonium perchlorate” with different equivalent ratios of their components have been calculated at different pressures. It has been established that a characteristic feature of detonation combustion of nanostructured silicon with a solid-phase oxidant is the stationary velocity of motion of the detonation front with a significant defect (10–15%) with respect to the Chapman–Jouguet detonation velocity. The detonation (supersonic) and subsonic regimes of combustion of nanostructured silicon with a solid-phase oxidant have been determined.
doi_str_mv	10.1007/s10891-020-02249-7
format	Article
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subjects	Analysis Classical Mechanics Combustion Complex Systems Engineering Engineering Thermodynamics Heat and Mass Transfer Heat and Mass Transfer in Combustion Processes Industrial Chemistry/Chemical Engineering Silicon Thermodynamics
title	On the Mechanism of Detonation Combustion of Nanostructured Silicon with a Solid-Phase Oxidant
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