Experimental and numerical study of polyoxymethylene (Aldrich) combustion in counterflow
| Autor: | Artem A. Shaklein, A.I. Karpov, A. A. Paletsky, Andrei Aleksandrovich Bolkisev, Oleg P. Korobeinichev, Amit Kumar, Roman K. Glaznev, Andrey G. Shmakov, Munko B. Gonchikzhapov |
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| Rok vydání: | 2019 |
| Předmět: |
Materials science
010304 chemical physics General Chemical Engineering Diffusion flame General Physics and Astronomy Energy Engineering and Power Technology Thermodynamics 02 engineering and technology General Chemistry Combustion Solid fuel Mass spectrometry 01 natural sciences Fuel Technology 020401 chemical engineering Mass transfer 0103 physical sciences Heat transfer Combustor Physics::Chemical Physics 0204 chemical engineering Quadrupole mass analyzer |
| Zdroj: | Combustion and Flame. 205:358-367 |
| ISSN: | 0010-2180 |
| DOI: | 10.1016/j.combustflame.2019.04.032 |
| Popis: | The burning behavior of polyoxymethylene in the counterflow of oxidizing air has been studied experimentally and numerically. Measurements have been performed using a specially designed burner. The temperature profiles were measured in gas phases by a microthermocouple technique. The burning surface temperature and the mass burning rates of solid fuel were determined. The chemical structure of counterflow flame was investigated using the mass spectrometric sampling by microprobe. The composition of the gas sample was analyzed on-line with a mass spectrometric complex (Hiden HPR 60), based on a quadrupole mass spectrometer. The species CH2O, CO, CO2, H2O, O2, N2 were identified and their concentration profiles were measured. The composition of products and kinetic parameters of POM thermal degradation have been determined by mass spectrometry and thermogravimetric analysis. Quasi one-dimensionality of considered diffusion flame has been established experimentally, which allows analysis of flame parameters in relation to the only coordinate normal to the solid fuel's burning surface and substantially simplifies the theoretical description. Predictions have been performed by a coupled model describing feedback heat and mass transfer between gas-phase flame and polymeric solid fuel. A two-dimensional elliptic equation in axisymmetric formulation has been employed to simulate heat transfer in solid fuel, and a set of one-dimensional hyperbolic equations has been used to determine the solid-to-gas conversion degree of the pyrolysis reaction. Gas-phase formulation is presented by one-dimensional conservation equations for multi-component flow with a detailed kinetic mechanism of combustion. Numerical results showed good agreement with the measurements for temperature and species concentration profiles, as well as for the mass burning rate and the surface temperature of solid fuel. |
| Databáze: | OpenAIRE |
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