Optimization of Impact Energy of TIG Mild Steel Welds Using RSM
Abstract
TIG welding, is about the most popular welding method, which finds its applications in the fabrication industry. The integrity and service life of engineering structures is a very important factor in the welding technology sector, one of the problem facing the fabrication industry is the control of the process input parameters to obtain a good welded joint. Research has shown that one of the practical ways to improving on weld qualities is to optimize the input process parameters. The aim of this study is to optimize the impact energy of TIG mild steel welds using RSM with the purpose of achieving the highest impact energy.In this study, twenty experimental runs were carried out, each experimental run comprising the current, voltage and gas flow rate, the TIG welding process was used to join two pieces of mild steel plates measuring 60 x40 x10 mm, the tensile strength was measured respectively. Thereafter the data collected from the experimental results was analysed with the RSM
Analysis of variance (ANOVA) a p-value of 0.0001 which is <0.005 indicates that the model is significant. To validate the significance and adequacy of the model based on its ability to optimize the ultimate impact energythe goodness of fit statistics showns that the model posses an R2 value of 0.705989 and R2 adjusted of 0.537617a noise to signal ratio of 7.89717 was realized, a ratio greater tha 4 is desired indicating thatt the model possesed adequate signal to predict the target response.the result shows that a combination of current 90 amps,voltage 22volts and gas flow rate 13lit/min will produce an optimum UTS of 381Mpa and impact energyof 116.6898J with a desiribility value of 0.889.
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ISSN (Paper)2224-6096 ISSN (Online)2225-0581
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