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Simplified multiple equations' inverse problem of vented vessels subjected to internal gas explosions
Institution:1. Aeronautical Technology Directorate, Japan Aerospace Exploration Agency, 7-44-1 Jindaijihigashi, Chofu, Tokyo, 182-8522, Japan;2. Department of Advanced Energy, The University of Tokyo, 5-1-5 Kashiwanoha, Kashiwa, Chiba, 277-8561, Japan;1. CIMEC, Centro de Investigación de Métodos Computacionales, UNL, CONICET, Colectora Ruta Nacional 168s/n, Predio CONICET “Dr Alberto Cassano” Santa Fe 3000, Argentina;2. Universidad Tecnológica Nacional - Facultad Regional Concepción del Uruguay, (UTN-FRCU), Ing. Pereyra 676, Concepción del Uruguay 3260, Argentina;3. Universidad Tecnológica Nacional - Facultad Regional Santa Fe,(UTN-FRSF), Lavaise 610, Santa Fe 3000, Argentina;4. Universidad Nacional del Litoral - Facultad de Ingeniería y Ciencias Hídricas, (UNL-FICH), Ciudad Universitaria, Santa Fe 3000, Argentina
Abstract:This paper analyses the experimental data reported by Höchst and Leuckel (1998) for combustion in partially confined vessels and uses the data from these experiments to establish the burning rate based on a simplified model for the combustion process in such vessels. The model establishes three fundamental parameters which are necessary in characterizing the combustion process. These are: i) the burning rate, ii) the fraction of vent area occupied by burnt gas (or discharge sub-model), and iii) the vent area model (if cover mechanisms with variable vent areas are utilized). A set of independent equations is derived to determine the burning rate according to conservation of mass and volume for each gas fraction separately along with a general equation based on general volume conservation. Using this method we are able to describe the combustion process and examine the effect of various discharge models. The advantages of the model presented here include rapid applicability and a valuable analysis to derive mass burn rate and other useful parameters using experimental data from vented explosions with reasonable residual reactant values. Based on these results, the correct interpretation of the obtained burning rate can be used in order to explain the correct prediction of flame velocity and position according to a reasonable discharge model. The paper also evaluates the suitability of several discharge models for phenomenological models of vented explosions. The most appropriate is a Heaviside step function which considers that only unburnt gas is initially expelled, with that component decreasing and the burnt gas component increasing until finally only burnt gas is expelled. The obtained results in this study can be used to predict the burning rate behavior and the combustion process of similar problems.
Keywords:Gas explosion  Phenomenological model  Inverse problem  Discharge sub-model  Variable burning rate
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