M. Campomanes scite author profile

M. Campomanes

5Publications

88Citation Statements Received

0Citation Statements Given

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222

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

Campomanes¹,

Altintaş

2003

167

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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.

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Optimization of Continuous Dress Creep-Feed Form Grinding Process

Guo¹,

Campomanes²,

Mcintosh³

et al. 2003

CIRP Annals

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Model-Based Monitoring and Control of Continuous Dress Creep-Feed Form Grinding

Guo¹,

Campomanes²,

Mcintosh³

et al. 2004

CIRP Annals

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Dynamics of milling flexible structures

Campomanes¹

1998

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An Improved Time Domain Simulation for Dynamic Milling at Small Radial Immersions and Large Depths of Cut

Campomanes¹,

Altintaş

2001

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This paper presents an improved time domain model for milling, which can simulate vibratory cutting conditions at very small radial widths of cut and large depths of cut. The improved kinematics model allows simulation of very small radial immersions. The varying dynamics modeled along the cutting depth allows milling with very flexible cutters and/or flexible workpieces at very deep cuts to be simulated. 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.

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M. Campomanes

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

Optimization of Continuous Dress Creep-Feed Form Grinding Process

Model-Based Monitoring and Control of Continuous Dress Creep-Feed Form Grinding

Dynamics of milling flexible structures

An Improved Time Domain Simulation for Dynamic Milling at Small Radial Immersions and Large Depths of Cut

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