%L scholars5045
%J MATEC Web of Conferences
%O cited By 0; Conference of 4th International Conference on Production, Energy and Reliability, ICPER 2014 ; Conference Date: 3 June 2014 Through 5 June 2014; Conference Code:106620
%R 10.1051/matecconf/20141304003
%D 2014
%K Finite element method; Heat transfer; Stainless steel, 304 stainless steel; 3D finite element model; Crystal morphologies; Finite element modelling; Maximum temperature; Oxyacetylene flame; Temperature patterns; Type 304 stainless steel, Temperature distribution
%X A 3D Finite element model was developed to analyse the conduction temperature distribution on type 304 stainless steel workpiece. An experimental heating-only test was conducted using the input parameters from FEM model which predicted the temperature field on the 304 stainless steel work pieces. Similar temperature pattern was noticed for both the FEM model as well as the experimental. Conduction was observed to be the dominant heat transfer mode. Maximum temperatures were observed to occur at the regions of contact between flame heat and the work pieces. Maximum temperature attained during the two investigated runs was 355°C. Even so austenite crystal morphology was retained on the preheated workpiece. © 2014 Owned by the authors, published by EDP Sciences.
%A A.U. Alkali
%A T.L. Ginta
%A A.M. Abdul-Rani
%I EDP Sciences
%V 13
%T Finite element modelling of a pattern of temperature distribution during travelling heat source from oxyacetylene flame
%C Kuala Lumpur