An Improved Time Domain Simulation for Dynamic Milling at Small Radial Immersions

Marc L.  Campomanes; Yusuf  Altintas

Source: Journal of Manufacturing Science and Engineering:;2003:;volume( 125 ):;issue: 003::page 416

Author:

Marc L. Campomanes

Yusuf Altintas

DOI: 10.1115/1.1580852

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: This paper presents an improved milling time domain model to simulate vibratory cutting conditions at very small radial widths of cut. The improved kinematics model allows simulation of very small radial immersions. The model can predict forces, surface finish, and chatter stability, accurately accounting for non-linear effects that are difficult to model analytically. The discretized cutter and workpiece kinematics and dynamic models are used to represent the exact trochoidal motion of the cutter, and to investigate the effects of forced vibrations and changing radial immersion due to deflection and vibrations on chatter stability. Three dimensional surface finish profiles are predicted and are compared to measured results. Stability lobes generated from the time domain simulation are also shown for various cases.

keyword(s): Force , Stability , Simulation , Vibration , Chatter , Cutting , Milling , Thickness , Engineering simulation , Deflection , Finishes AND Kinematics ,

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An Improved Time Domain Simulation for Dynamic Milling at Small Radial Immersions

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contributor author	Marc L. Campomanes
contributor author	Yusuf Altintas
date accessioned	2017-05-09T00:10:42Z
date available	2017-05-09T00:10:42Z
date copyright	August, 2003
date issued	2003
identifier issn	1087-1357
identifier other	JMSEFK-27739#416_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/128686
description abstract	This paper presents an improved milling time domain model to simulate vibratory cutting conditions at very small radial widths of cut. The improved kinematics model allows simulation of very small radial immersions. The model can predict forces, surface finish, and chatter stability, accurately accounting for non-linear effects that are difficult to model analytically. The discretized cutter and workpiece kinematics and dynamic models are used to represent the exact trochoidal motion of the cutter, and to investigate the effects of forced vibrations and changing radial immersion due to deflection and vibrations on chatter stability. Three dimensional surface finish profiles are predicted and are compared to measured results. Stability lobes generated from the time domain simulation are also shown for various cases.
publisher	The American Society of Mechanical Engineers (ASME)
title	An Improved Time Domain Simulation for Dynamic Milling at Small Radial Immersions
type	Journal Paper
journal volume	125
journal issue	3
journal title	Journal of Manufacturing Science and Engineering
identifier doi	10.1115/1.1580852
journal fristpage	416
journal lastpage	422
identifier eissn	1528-8935
keywords	Force
keywords	Stability
keywords	Simulation
keywords	Vibration
keywords	Chatter
keywords	Cutting
keywords	Milling
keywords	Thickness
keywords	Engineering simulation
keywords	Deflection
keywords	Finishes AND Kinematics
tree	Journal of Manufacturing Science and Engineering:;2003:;volume( 125 ):;issue: 003
contenttype	Fulltext

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