Numerical Simulation of NO Formation in Methane, Methanol and Methyl Formate in a Homogeneous System

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dc.contributor.author Tanui, J.K.
dc.contributor.author Kioni, P.K.
dc.date.accessioned 2012-09-26T13:56:32Z
dc.date.accessioned 2013-07-19T07:42:43Z
dc.date.available 2012-09-26T13:56:32Z
dc.date.available 2013-07-19T07:42:43Z
dc.date.issued 2012
dc.identifier.uri http://elearning.jkuat.ac.ke/journals/ojs/index.php/sri/article/view/288/375
dc.identifier.uri http://hdl.handle.net/123456789/1584
dc.identifier.uri http://hdl.handle.net/123456789/716
dc.description An article presented in Sustainable Research and Innovation Proceedings 2012 en_US
dc.description.abstract In this study, methane/air, methanol/air, and methyl formate/air stoichiometric mixtures have been numerically simulated at constant volume, low pressure of 2.7 atm, and temperature ranging from 1000 K to 1950 K with an aim to establish the impact of fuel oxygenation on NO formation. These conditions represent those behind a reflected shock in a shock tube, which is modeled as adiabatic homogeneous mixture with constant internal energy and constant volume. Various chemical kinetic mechanisms have been employed and extensively tested so as to ensure validity of the results. A comparison of NO profiles and other radicals- CH, HCN, N, and N2- that are dominant in its formation have been done. Since the initial temperatures are high, the flame temperatures attained by all the mixtures are also high; from approximately 2800 to 3100 K for initial temperatures of 1000 and 1950 K respectively. Therefore, NO are formed mostly through thermal NO mechanism with prompt NO being less significant. It has been observed that at very high temperatures the difference in N and NO formation in the three fuels is not very significant (same order of magnitude) as compared to that observed in relatively low temperatures attained by freely propagating and diffusion flames. At high temperatures the major rate-limiting steps for NO formation, involving high activation energy are N2 + O =NO + N (318.4 KJ/mol), CH2 + N2 =HCN + NH (309.69 KJ/mol) and N2 + C = CN + N (187.90 KJ/mol). en_US
dc.language.iso en en_US
dc.publisher JKUAT en_US
dc.subject zeldovich mechanism en_US
dc.subject methane en_US
dc.subject methyl formate en_US
dc.subject NO en_US
dc.title Numerical Simulation of NO Formation in Methane, Methanol and Methyl Formate in a Homogeneous System en_US
dc.type Article en_US


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