DESIGN, MODELLING AND SIMULATION OF SIDE AND FACE MILLING CUTTER

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dc.contributor.authorRufus Ogbuka Chime
dc.contributor.authorSamuel I.Ukwuaba
dc.contributor.authorAbdulrahim Abdulbaqi Toyin
dc.contributor.authorfrancis ikechukwu Azuka
dc.contributor.authorBenjamin Ibe Chukwu
dc.contributor.authorAnthony Igwe
dc.date.accessioned2026-04-02T15:47:12Z
dc.date.available2026-04-02T15:47:12Z
dc.date.issued2015-09-10
dc.description.abstractTraditionally, the design field has been identified with particular end products, e.g., mechanical design, electrical design, ship design. In these fields, design work is largely based on specific techniques to foster certain product characteristics and principles . Computer technology has touched all areas of today’s life, impacting how we obtain railway tickets, shop online and receive medical advice from remote location. Computer-based design analysis is nowadays a common activity in most development projects. The scope of this work includes, to design, model and simulate side and face milling cutter, to select cutting tool materials and also to detailed factor safety in design . When new software and manufacturing processes are introduced, traditional empirical knowledge is unavailable and considerable effort is required to find starting design concepts. Modeling and simulation of cutting processes have the potential for improving cutting tool designs and selecting optimum conditions, especially in advanced applications such as high-speed milling. Milling operation is today the most effective and productive manufacturing method for roughing and finishing large surfaces of metallic parts.. The model simulates precisely the tool kinematics and considers the effect of the cutting geometry on the resulting roughness. The accuracy of the simulation model has been thoroughly verified, with the aid of a wide variety of experiments. Metal cutting process is not only a material removal process, but also a deformation process where deformation is highly concentrated in a small zone . Thereby, it can be investigated as a chip formation process and simulated using Finite Element Method (FEM) techniques. The main advantage of such an approach is to be able to predict all process variables arisen in the deformation zones. However, material flow characteristics at the high temperature, strain-rate and strain, encountered during cutting process, are very important for predicting chip flow, cutting forces, temperatures and stresses.
dc.identifier.issn2278-7763
dc.identifier.urihttps://kwasuspace.kwasu.edu.ng/handle/123456789/6551
dc.language.isoen
dc.titleDESIGN, MODELLING AND SIMULATION OF SIDE AND FACE MILLING CUTTER
dc.typeArticle
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