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Analysis and Optimization of the Machining Process in Brass Machining
Machining technology plays a crucial role in manufacturing, particularly in the processing of lead-free brass. Indexable inserts made from carbide and ceramic are essential components in machining, and their geometry significantly influences the efficiency and quality of the ma-chining process. Innovative methods for modifying cutting edge radii offer potential for opti-mizing machining processes. Understanding the impact of these geometric parameters on the coefficient of friction can lead to significant improvements in process stability and tool life.
Keywords: Machining Process, Brass Machining Indexable Inserts, Cutting Edge Radius, Coefficient of Friction, Carbide Tools, Ceramic Tools, Tool Geometry, Planing Process
Process Optimization, Machining Parameters
The aim of this project is to modify carbide and ceramic indexable inserts using an innovative method to create different cutting edge radii. These modified inserts will then be tested in var-ious machining trials using a planing process on lead-free brass. The focus is on investigating the influence of geometric and process parameters on the coefficient of friction. This project offers a practical investigation of the interactions between tool geometry and machining pro-cesses and contributes to improving manufacturing technology in the machining of lead-free brass.
The aim of this project is to modify carbide and ceramic indexable inserts using an innovative method to create different cutting edge radii. These modified inserts will then be tested in var-ious machining trials using a planing process on lead-free brass. The focus is on investigating the influence of geometric and process parameters on the coefficient of friction. This project offers a practical investigation of the interactions between tool geometry and machining pro-cesses and contributes to improving manufacturing technology in the machining of lead-free brass.
The primary goal of this project is to investigate and optimize the machining process of lead-free brass by modifying the cutting edge radii of carbide and ceramic indexable inserts. This involves conducting machining trials, analyzing the influence of geometric and process parameters on the coefficient of friction, and identifying optimal parameters to enhance process stability and tool life.
The primary goal of this project is to investigate and optimize the machining process of lead-free brass by modifying the cutting edge radii of carbide and ceramic indexable inserts. This involves conducting machining trials, analyzing the influence of geometric and process parameters on the coefficient of friction, and identifying optimal parameters to enhance process stability and tool life.
Yves Locher, PFA EO 93, yves.locher@inspire.ch, +41 44 632 54 84
Hagen Klippel, PFA F 44, klippel@iwf.mavt.ethz.ch, +41 44 632 94 79
Vishal Garg, PFA E 93, vishal.garg@inspire.ch
Yves Locher, PFA EO 93, yves.locher@inspire.ch, +41 44 632 54 84 Hagen Klippel, PFA F 44, klippel@iwf.mavt.ethz.ch, +41 44 632 94 79 Vishal Garg, PFA E 93, vishal.garg@inspire.ch