Productivity considerations in face milling

被引：0

作者：

Kundrák J. ^{[1
]}

Molnár V. ^{[2
]}

Deszpoth I. ^{[1
]}

Makkai T. ^{[1
]}

机构：

[1] University of Miskolc, Institute of Manufacturing Science

[2] University of Miskolc, Institute of Management Science

来源：

Materials Science Forum | 2019年 / 952卷

关键词：

Face milling; Material removal rate; Precision machining;

D O I：

10.4028/www.scientific.net/MSF.952.66

中图分类号：

学科分类号：

摘要：

The kinematic versions and applied tools of milling allow for the machining of several surfaces and surface combinations, making it a versatile and widely applied procedure. Face milling for cutting is used for the high productivity manufacturing of prismatic components. Naturally, the enhancement of productivity is a primary goal for manufacturing companies; this study analyzes the efficiency of material removal, which directly influences the time parameters characterizing production performed by face milling. The focus of the paper is to identify the selection of technological data (feed, feed rate, cutting speed, diameter of milling head) that can reduce the machining time or increase the values of material removal rate. Cutting experiments were carried out for machining prismatic components from AlSi9Cu3(Fe) aluminum alloy by diamond tools. It was found that within the performance limits of the manufacturing system it is possible to save a significant amount of manufacturing time while retaining the specified geometric accuracy and surface quality of the component. © 2019 Trans Tech Publications Ltd, Switzerland.

引用

页码：66 / 73

页数：7

共 20 条

[1] Felho C., Kundrak J., Characterization of topography of cut surface based on theoretical roughness indexes, Key Engineering Materials, 496, pp. 194-199, (2012)
[2] Felho C., Kundrak J., Comparison of theoretical and real surface roughness in face milling with octagonal and circular inserts, Key Engineering Materials, 581, pp. 360-365, (2014)
[3] Kundrak J., Markopoulos A.P., Makkai T., Deszpoth I., Nagy A., Analysis of the Effect of Feed on Chip Size Ratio and Cutting Forces in Face Milling for Various Cutting Speeds, Manufacturing Technology, 18, 3, pp. 431-438, (2018)
[4] Yeh L.-J., Lan T.-S., The optimal control of material removal rate with fixed tool life and speed limitation, Journal of Materials Processing Technology, 121, pp. 238-242, (2002)
[5] Hernandez A.E.B., Beno T., Repo J., Wretland A., Integrated optimization model for cutting data selection based on maximal MRR and tool utilization in continuous machining operations, CIRP Journal of Manufacturing Scienca and Technology, 13, pp. 46-50, (2016)
[6] Kumar R., Bilga P.S., Singh S., Multi objective optimization using different methods of assigning weights to energy consumption responses, surface roughness and material removal rate during rough turning operation, Journal of Cleaner Production, 164, pp. 45-57, (2017)
[7] Hernandez A.E.B., Beno T., Repo J., Wretland A., Analysis of tool utilization from material removal rate perspective, Procedia CIRP, 29, pp. 109-113, (2015)
[8] Zhong Q., Tang R., Peng T., Decision rules for energy consumption minimization during material removal process in turning, Journal of Cleaner Production, 140, pp. 1819-1827, (2017)
[9] Das M.K., Kumar K., Barman T.K., Sahoo P., Optimization of process parameters in plasma arc cutting of en 31 steel based on MRR and multiple roughness characteristics using grey relational analysis, Procedia Materials Science, 5, pp. 1550-1559, (2014)
[10] Buj-Corral I., Vivancos-Calvet J., Coba-Salcedo M., Modelling of surface finish and material removal rate in rough honing, Precision Engineering, 38, pp. 100-108, (2014)

← 1 2 →