Abstract
This paper investigates machining of Inconel 825 with and without cryogenic treatment. The micromachining of Inconel 825 was done using CNC lathe and PVD coated (Multilayer TiAlN/TiN) carbide inserts as a cutting tool. Improvement in output parameters was observed when the workpiece material was treated cryogenically. The experiments were designed using the Taguchi method. A mathematical model has been established using the regression analysis of the experimental results. The independent variables in the developed mathematical model are cutting speed (Vc), feed (f), and depth of cut (d). The surface roughness and temperature are the dependent variables. The effect of independent variables on dependent variables with and without cryogenic treatment of the workpiece (i.e., Inconel 825) was analyzed. Nine experiments were conducted on a CNC lathe machine. Surface roughness of the workpieces was measured after machining the workpieces and the temperature was measured while machining of the workpieces. A mathematical model was formulated by using regression analysis. Based on the developed mathematical model surface finish was calculated.
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Bhivsane, S.V., Chel, A.L. (2021). Comparative Experimental Analysis of Machining Parameters for Inconel 825 on Cryogenic Treatment. In: Pandey, P.M., Kumar, P., Sharma, V. (eds) Advances in Production and Industrial Engineering. Lecture Notes in Mechanical Engineering. Springer, Singapore. https://doi.org/10.1007/978-981-15-5519-0_9
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