Modeling of Tooling-Workpiece Interactions on Random Surfaces

Hitesh Kataria; Andres L. Carrano; Brian K. Thorn

doi:10.1155/2012/807018

Modeling of Tooling-Workpiece Interactions on Random Surfaces

Hitesh Kataria, Andres L. Carrano, Brian K. Thorn

Research output: Contribution to journal › Article › peer-review

Abstract

Abrasive processes, commonly employed in manufacturing, are difficult to model because they rely on brittle particles with unknown geometry and multiple points of contact. Newly developed microreplicated abrasives allow for control of abrasive grit properties such as size, shape, and distribution. This paper proposes and validates a parametric model of abrasive machining that allows for studying the interaction of this particular tooling with randomly generated surfaces. In this work, the parameters of a probability distribution function that represents the workpiece surface are approximated by profilometry data. Monte Carlo simulation is used to account for inter- and intraspecimen variability. A geometric representation is used to mathematically represent the interaction between workpiece and tool. The results show good correlation between theoretical and actual values. This approach could be used to aid in tool geometry design as well as in process parameter optimization.

Original language	American English
Journal	Advances in Mechanical Engineering
Volume	4
DOIs	https://doi.org/10.1155/2012/807018
State	Published - Jan 1 2012
Externally published	Yes

Keywords

Modeling
Tooling-workpiece interactions
Random surfaces
Mechanical engineering

Disciplines

Engineering
Materials Science and Engineering
Mechanical Engineering

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Cite this

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title = "Modeling of Tooling-Workpiece Interactions on Random Surfaces",

abstract = " Abrasive processes, commonly employed in manufacturing, are difficult to model because they rely on brittle particles with unknown geometry and multiple points of contact. Newly developed microreplicated abrasives allow for control of abrasive grit properties such as size, shape, and distribution. This paper proposes and validates a parametric model of abrasive machining that allows for studying the interaction of this particular tooling with randomly generated surfaces. In this work, the parameters of a probability distribution function that represents the workpiece surface are approximated by profilometry data. Monte Carlo simulation is used to account for inter- and intraspecimen variability. A geometric representation is used to mathematically represent the interaction between workpiece and tool. The results show good correlation between theoretical and actual values. This approach could be used to aid in tool geometry design as well as in process parameter optimization.",

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AU - Carrano, Andres L.

AU - Thorn, Brian K.

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N2 - Abrasive processes, commonly employed in manufacturing, are difficult to model because they rely on brittle particles with unknown geometry and multiple points of contact. Newly developed microreplicated abrasives allow for control of abrasive grit properties such as size, shape, and distribution. This paper proposes and validates a parametric model of abrasive machining that allows for studying the interaction of this particular tooling with randomly generated surfaces. In this work, the parameters of a probability distribution function that represents the workpiece surface are approximated by profilometry data. Monte Carlo simulation is used to account for inter- and intraspecimen variability. A geometric representation is used to mathematically represent the interaction between workpiece and tool. The results show good correlation between theoretical and actual values. This approach could be used to aid in tool geometry design as well as in process parameter optimization.

AB - Abrasive processes, commonly employed in manufacturing, are difficult to model because they rely on brittle particles with unknown geometry and multiple points of contact. Newly developed microreplicated abrasives allow for control of abrasive grit properties such as size, shape, and distribution. This paper proposes and validates a parametric model of abrasive machining that allows for studying the interaction of this particular tooling with randomly generated surfaces. In this work, the parameters of a probability distribution function that represents the workpiece surface are approximated by profilometry data. Monte Carlo simulation is used to account for inter- and intraspecimen variability. A geometric representation is used to mathematically represent the interaction between workpiece and tool. The results show good correlation between theoretical and actual values. This approach could be used to aid in tool geometry design as well as in process parameter optimization.

KW - Modeling

KW - Tooling-workpiece interactions

KW - Random surfaces

KW - Mechanical engineering

U2 - 10.1155/2012/807018

DO - 10.1155/2012/807018

M3 - Article

VL - 4

JO - Advances in Mechanical Engineering

JF - Advances in Mechanical Engineering

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