Details

Title

Monitoring of tool vibration for magnetorheological fluid controlled bar during turning of hardened AISI4340 steel

Journal title

Archive of Mechanical Engineering

Yearbook

2015

Volume

vol. 62

Numer

No 2

Authors

Keywords

hard turning ; tool vibration ; magnetorheological (MR) damper ; tool condition monitoring ; acoustic emission ; skewness ; kurtosis

Divisions of PAS

Nauki Techniczne

Coverage

237-255

Publisher

Polish Academy of Sciences, Committee on Machine Building

Date

14.08.2015

Type

Artykuły / Articles

Identifier

ISSN 0004-0738, e-ISSN 2300-1895

References

Sam Paul (2013), ANN assisted Sensor Fusion model to predict tool wear during Hard turning with Minimal Fluid Application of Machining and Machinability of Materials, International Journal, 13, 398. ; Scheffer (2003), Development of a tool wear monitoring system for hard turning of Machine Tools and Manufacture, International Journal, 43, 973. ; Dornfeld (1992), Application of acoustic emission techniques in manufacturing, International, 25, 259. ; Sam Paul (2013), Performance evaluation of hard turning of AISI steel with minimal fluid application in the presence of semi - solid lubricants of Engineering Tribology, Journal, 227, 739. ; Sam Paul (2012), Effect of magnetorheological damper on tool vibration during hard turning of Frontiers in Mechanical Engineering, Journal, 7, 410. ; Klocke (1997), Dry cutting of the CIRP, Annals, 46, 519. ; Deqing (2009), Magnetorheological fluidcontrolled boring bar for chatter suppression of Materials Processing Technology, Journal, 209, 1861. ; Narutaki (1979), Tool Wear and Cutting Temperature of CBN Tools in Machining of Hardened Steels of the CIRP, Annals, 28, 23. ; Sharma (2006), Tool wear estimation for turning operations of Mechanical Engineering, Journal, 57, 141. ; Prakash (2013), In - process tool condition monitoring using acoustic emission sensor in mocroendmilling and Technology, Machining Science, 17, 209, doi.org/10.1080/10910344.2013.780541 ; Wang (1999), Chatter suppression based on nonlinearvibration characteristic of electrorheological fluids of Machine Tools and Manufacture, International Journal, 39, 1925. ; Xialoi (2002), A brief review : acoustic method for tool wear monitoring during turning of Machine Tools & Manufacture, International Journal, 42, 157. ; Sam Paul (2012), A multi - sensor fusion model based on an artificial neural network to predict tool wear during hard turning of Engineering Manufacture, Journal, 226, 853. ; Altintas (2012), Manufacturing Automation : Metal Cutting Mechanics Machine Tool Vibrations and CNC Design second edition Cambridge University Press, Cambridge. ; Varadarajan (2002), Investigations on hard turning with minimal fluid application and its comparison with dry and wet turning of Machine Tools & Manufacture, International Journal, 42, 193. ; Ginder (1996), Rheology of magnetorheological fluids : models and measurements of Modern Physics, International Journal B, 10, 3293. ; Genc (2002), Rheological Properties of Magnetorheological Fluids Materials and Structures, Smart, 11, 140. ; Sam Paul (2014), Effect of magnetic field on damping ability of magnetorheological damper during hard turning of Civil and Mechanical Engineering, Archives, 14, 433. ; Tansel (2002), Tool wear estimation in micro machining - part tool usage - cutting force relationship of Machine Tools & Manufacture, International Journal, 40, 599. ; Bhaskaran (2012), Monitoring of hard turning using acoustic emission signal of Mechanical Science and Technology, Journal, 26, 609. ; Dornfeld (1980), Acoustic emission during orthogonal metal cutting of Mechanical Science, International Journal, 22, 285. ; Sam Paul (2015), Effect of magnetorheological damper on tool wear during hard turning with minimal fluid application of Civil and Mechanical Engineering, Archives, 15, 124. ; Spencer Jr (1997), Phenomenological Model of a Magnetorheological Damper of Engineering Mechanics, Journal, 123, 230.

DOI

10.1515/meceng-2015-0014

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