Multi-point coupling for tool point receptance prediction

Tony Schmitz; Andrew Honeycutt; Michael Gomez; Michael Stokes; Emma Betters

doi:10.1016/j.jmapro.2019.03.043

Multi-point coupling for tool point receptance prediction

Tony Schmitz, Andrew Honeycutt, Michael Gomez, Michael Stokes, Emma Betters

Advanced Machining and Machine Tools Res

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

25 Scopus citations

Abstract

This paper describes a multi-point receptance coupling substructure analysis (RCSA) technique for tool point receptance prediction. The portion of the tool inside the holder is coupled to the portion of the holder that clamps the tool at multiple points along the insertion length. The coupling can be rigid or flexible-damped. The procedure is described analytically and then experimental results are presented. The tool point receptances, or frequency response functions, for four carbide tool blank diameters are tested at multiple extension lengths and compared to predictions for an ER32 collet connection. Stiffness matrices are identified for each of the tool blank diameters and reported. Given the predicted tool point receptances, milling process models can be used to select optimized operating parameters at the process planning stage.

Original language	English
Pages (from-to)	2-11
Number of pages	10
Journal	Journal of Manufacturing Processes
Volume	43
DOIs	https://doi.org/10.1016/j.jmapro.2019.03.043
State	Published - Jul 2019

Funding

This material is based on work supported by the National Science Foundation under Grant No. CMMI-1561221. This material is based on work supported by the National Science Foundation under Grant No. CMMI-1561221 .

Keywords

Dynamics
Milling
Receptance coupling substructure analysis

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10.1016/j.jmapro.2019.03.043

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title = "Multi-point coupling for tool point receptance prediction",

abstract = "This paper describes a multi-point receptance coupling substructure analysis (RCSA) technique for tool point receptance prediction. The portion of the tool inside the holder is coupled to the portion of the holder that clamps the tool at multiple points along the insertion length. The coupling can be rigid or flexible-damped. The procedure is described analytically and then experimental results are presented. The tool point receptances, or frequency response functions, for four carbide tool blank diameters are tested at multiple extension lengths and compared to predictions for an ER32 collet connection. Stiffness matrices are identified for each of the tool blank diameters and reported. Given the predicted tool point receptances, milling process models can be used to select optimized operating parameters at the process planning stage.",

keywords = "Dynamics, Milling, Receptance coupling substructure analysis",

author = "Tony Schmitz and Andrew Honeycutt and Michael Gomez and Michael Stokes and Emma Betters",

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AU - Schmitz, Tony

AU - Honeycutt, Andrew

AU - Gomez, Michael

AU - Stokes, Michael

AU - Betters, Emma

PY - 2019/7

Y1 - 2019/7

N2 - This paper describes a multi-point receptance coupling substructure analysis (RCSA) technique for tool point receptance prediction. The portion of the tool inside the holder is coupled to the portion of the holder that clamps the tool at multiple points along the insertion length. The coupling can be rigid or flexible-damped. The procedure is described analytically and then experimental results are presented. The tool point receptances, or frequency response functions, for four carbide tool blank diameters are tested at multiple extension lengths and compared to predictions for an ER32 collet connection. Stiffness matrices are identified for each of the tool blank diameters and reported. Given the predicted tool point receptances, milling process models can be used to select optimized operating parameters at the process planning stage.

AB - This paper describes a multi-point receptance coupling substructure analysis (RCSA) technique for tool point receptance prediction. The portion of the tool inside the holder is coupled to the portion of the holder that clamps the tool at multiple points along the insertion length. The coupling can be rigid or flexible-damped. The procedure is described analytically and then experimental results are presented. The tool point receptances, or frequency response functions, for four carbide tool blank diameters are tested at multiple extension lengths and compared to predictions for an ER32 collet connection. Stiffness matrices are identified for each of the tool blank diameters and reported. Given the predicted tool point receptances, milling process models can be used to select optimized operating parameters at the process planning stage.

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Multi-point coupling for tool point receptance prediction

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