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Investigation of Cutting Forces for Thin Layers when Planing and Milling

Authors: Shevchenko A.Yu., Popov A.Yu., Drozdov I.N., Blokhin D.A., Kisel A.G., Nekrylov E.V. Published: 20.12.2021
Published in issue: #4(139)/2021  

DOI: 10.18698/0236-3941-2021-4-66-79

 
Category: Mechanical Engineering and Machine Science | Chapter: Technology and Equipment of Mechanical and Physical Processing  
Keywords: cutting forces, universal dynamometer, planing, milling, small chip sections, lubricating coolant

The problem of machining structural elements with removal of metal layers with thickness less than 0.01 mm by carbide tools, when the conditional radius of the blade rounding is less than or equal to the thickness of the cut layer, is considered. These cutting conditions can be considered constricted which requires research into cutting forces and chip shape. The problem of recording and measuring small cutting forces arising during blade machining of small grooves that serve for gas drainage in the manufacture of rubber products is solved. To measure forces, a lever fixed in a universal dynamometer, which has a supporting support with small friction, is used. Value of force moment measured with dynamometer can be used for optimization of cutting conditions, selection of tool geometry when processing small relief elements. Dependences of lever system cutting forces and displacements on the use of lubricant-cooling liquids, values of front angles during planing and milling with small-size tools are investigated. Experimental discrepancies between theoretical calculations of cutting forces according to classical and modern reference data and fixed results with the use of cutting liquids during cutting with small values of feed for carbide tools are found

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