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Prediction of cutting force based on machining parameters on AL7075‐T6 aluminum alloy by response surface methodology in end milling

A. Sethupathy, N. Shanmugasundaram

2021Materialwissenschaft und Werkstofftechnik15 citationsDOI

Abstract

Abstract Cutting forces modeling is the basic to understand the cutting process, which should be kept in minimum to reduce tool deflection, vibration, tool wear and optimize the process parameters in order to obtain a high quality product within minimum machining time. In this paper a statistical model has been developed to predict cutting force in terms of geometrical parameters such as rake angle, nose radius of cutting tool and machining parameters such as cutting speed, cutting feed and axial depth of cut. Response surface methodology experimental design was employed for conducting experiments. The work piece material is Aluminum (Al 7075‐T6) and the tool used is high speed steel end mill cutter with different tool geometry. The cutting forces are measured using three axis milling tool dynamometer. The second order mathematical model in terms of machining parameters is developed for predicting cutting forces. The adequacy of the model is checked by employing ANOVA. The direct effect of the process parameter with cutting forces are analyzed, which helps to select process parameter in order to keep cutting forces minimum, which ensures the stability of end milling process. The study observed that feed rate has the highest statistical and physical influence on cutting force.

Topics & Concepts

Rake angleEnd millMachiningMechanical engineeringDynamometerDeflection (physics)EngineeringCutting toolResponse surface methodologyRakeProcess (computing)Structural engineeringMaterials scienceComputer scienceMachine learningOpticsOperating systemPhysicsAdvanced machining processes and optimizationAdvanced Machining and Optimization TechniquesAdvanced Surface Polishing Techniques
Prediction of cutting force based on machining parameters on AL7075‐T6 aluminum alloy by response surface methodology in end milling | Litcius