Geometric Modeling of Engineered Abrasive Processes

Andres L. Carrano; James B. Taylor; Richard L. Lemaster

Geometric Modeling of Engineered Abrasive Processes

Andres L. Carrano, James B. Taylor, Richard L. Lemaster

Research output: Contribution to conference › Presentation

Abstract

One of the common issues that arises in abrasive machining is the inconsistency of the surface roughness within the same batch and under identical machining conditions. Recent advances in engineered abrasives have allowed replacement of the random arrangement of minerals on conventional belts with precisely shaped structures uniformly cast directly onto a backing material. This allows for abrasive belts that are more deterministic in shape, size, distribution, orientation, and composition. A computer model based on known tooling geometry was developed to approximate the asymptotic surface profile that was achievable under specific loading conditions. Outputs included the theoretical surface parameters, Rq, Ra, Rv, Rp, Rt, and Rsk. Experimental validation was performed with a custom-made abrader apparatus and using engineered abrasives on highly polished aluminum samples. Interferometric microscopy was used in assessing the surface roughness. Results include the individual effects of pyramid base width, pyramid height, attack angle, and indentation depth on the surface descriptors.

Original language	American English
State	Published - May 2001
Externally published	Yes
Event	Industrial Engineering Research Conference (IERC) - Orlando, FL Duration: May 1 2002 → …

Conference

Conference	Industrial Engineering Research Conference (IERC)
Period	5/1/02 → …

Keywords

Engineered Abrasives
Geometric Computer Model
Surface Roughness
Surface Generation
Abrasive Machining

Disciplines

Engineering

Cite this

@conference{c68aa0c9d8504bcc8d1b968f1b86111b,

title = "Geometric Modeling of Engineered Abrasive Processes",

abstract = " One of the common issues that arises in abrasive machining is the inconsistency of the surface roughness within the same batch and under identical machining conditions. Recent advances in engineered abrasives have allowed replacement of the random arrangement of minerals on conventional belts with precisely shaped structures uniformly cast directly onto a backing material. This allows for abrasive belts that are more deterministic in shape, size, distribution, orientation, and composition. A computer model based on known tooling geometry was developed to approximate the asymptotic surface profile that was achievable under specific loading conditions. Outputs included the theoretical surface parameters, Rq, Ra, Rv, Rp, Rt, and Rsk. Experimental validation was performed with a custom-made abrader apparatus and using engineered abrasives on highly polished aluminum samples. Interferometric microscopy was used in assessing the surface roughness. Results include the individual effects of pyramid base width, pyramid height, attack angle, and indentation depth on the surface descriptors.",

keywords = "Engineered Abrasives, Geometric Computer Model, Surface Roughness, Surface Generation, Abrasive Machining",

author = "Carrano, \{Andres L.\} and Taylor, \{James B.\} and Lemaster, \{Richard L.\}",

year = "2001",

month = may,

language = "American English",

note = "Industrial Engineering Research Conference (IERC) ; Conference date: 01-05-2002",

}

TY - CONF

T1 - Geometric Modeling of Engineered Abrasive Processes

AU - Carrano, Andres L.

AU - Taylor, James B.

AU - Lemaster, Richard L.

PY - 2001/5

Y1 - 2001/5

N2 - One of the common issues that arises in abrasive machining is the inconsistency of the surface roughness within the same batch and under identical machining conditions. Recent advances in engineered abrasives have allowed replacement of the random arrangement of minerals on conventional belts with precisely shaped structures uniformly cast directly onto a backing material. This allows for abrasive belts that are more deterministic in shape, size, distribution, orientation, and composition. A computer model based on known tooling geometry was developed to approximate the asymptotic surface profile that was achievable under specific loading conditions. Outputs included the theoretical surface parameters, Rq, Ra, Rv, Rp, Rt, and Rsk. Experimental validation was performed with a custom-made abrader apparatus and using engineered abrasives on highly polished aluminum samples. Interferometric microscopy was used in assessing the surface roughness. Results include the individual effects of pyramid base width, pyramid height, attack angle, and indentation depth on the surface descriptors.

AB - One of the common issues that arises in abrasive machining is the inconsistency of the surface roughness within the same batch and under identical machining conditions. Recent advances in engineered abrasives have allowed replacement of the random arrangement of minerals on conventional belts with precisely shaped structures uniformly cast directly onto a backing material. This allows for abrasive belts that are more deterministic in shape, size, distribution, orientation, and composition. A computer model based on known tooling geometry was developed to approximate the asymptotic surface profile that was achievable under specific loading conditions. Outputs included the theoretical surface parameters, Rq, Ra, Rv, Rp, Rt, and Rsk. Experimental validation was performed with a custom-made abrader apparatus and using engineered abrasives on highly polished aluminum samples. Interferometric microscopy was used in assessing the surface roughness. Results include the individual effects of pyramid base width, pyramid height, attack angle, and indentation depth on the surface descriptors.

KW - Engineered Abrasives

KW - Geometric Computer Model

KW - Surface Roughness

KW - Surface Generation

KW - Abrasive Machining

M3 - Presentation

T2 - Industrial Engineering Research Conference (IERC)

Y2 - 1 May 2002

ER -