Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials

V. Chandrasekharan; S. G. Kapoor; R. E. DeVor

Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials

V. Chandrasekharan, S. G. Kapoor, R. E. DeVor

Mechanical Science and Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

In this paper models are developed to predict the thrust and the torque forces at the different regions of cutting on a drill. The mechanistic approach adopted to develop these models exploits the geometry of the process, which is independent of the workpiece material. The models are calibrated to a particular material using the well-established relationships between chip load and cutting forces, modified to take advantage of the characteristics of the drill point geometry. The models are validated independently for the cutting lips and the chisel edge for drilling both metals and fiber-reinforced composite materials for a wide range of machining conditions and drill geometry. While the cutting-lips model predictions agree well with the experimental data for both materials, only the chisel-edge model proposed for metals agrees well with the experimental data.

Original language	English (US)
Title of host publication	Machining of Advanced Composites
Editors	M. Ramulu, R. Komanduri
Publisher	Publ by ASME
Pages	33-51
Number of pages	19
ISBN (Print)	079181033X
State	Published - 1993
Event	Proceedings of the 1993 ASME Winter Annual Meeting - New Orleans, LA, USA Duration: Nov 28 1993 → Dec 3 1993

Publication series

Name	American Society of Mechanical Engineers, Materials Division (Publication) MD
Volume	45

Other

Other	Proceedings of the 1993 ASME Winter Annual Meeting
City	New Orleans, LA, USA
Period	11/28/93 → 12/3/93

ASJC Scopus subject areas

General Engineering

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Chandrasekharan, V., Kapoor, S. G., & DeVor, R. E. (1993). Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials. In M. Ramulu, & R. Komanduri (Eds.), Machining of Advanced Composites (pp. 33-51). (American Society of Mechanical Engineers, Materials Division (Publication) MD; Vol. 45). Publ by ASME.

Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials. / Chandrasekharan, V.; Kapoor, S. G.; DeVor, R. E.
Machining of Advanced Composites. ed. / M. Ramulu; R. Komanduri. Publ by ASME, 1993. p. 33-51 (American Society of Mechanical Engineers, Materials Division (Publication) MD; Vol. 45).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Chandrasekharan, V, Kapoor, SG & DeVor, RE 1993, Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials. in M Ramulu & R Komanduri (eds), Machining of Advanced Composites. American Society of Mechanical Engineers, Materials Division (Publication) MD, vol. 45, Publ by ASME, pp. 33-51, Proceedings of the 1993 ASME Winter Annual Meeting, New Orleans, LA, USA, 11/28/93.

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abstract = "In this paper models are developed to predict the thrust and the torque forces at the different regions of cutting on a drill. The mechanistic approach adopted to develop these models exploits the geometry of the process, which is independent of the workpiece material. The models are calibrated to a particular material using the well-established relationships between chip load and cutting forces, modified to take advantage of the characteristics of the drill point geometry. The models are validated independently for the cutting lips and the chisel edge for drilling both metals and fiber-reinforced composite materials for a wide range of machining conditions and drill geometry. While the cutting-lips model predictions agree well with the experimental data for both materials, only the chisel-edge model proposed for metals agrees well with the experimental data.",

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N2 - In this paper models are developed to predict the thrust and the torque forces at the different regions of cutting on a drill. The mechanistic approach adopted to develop these models exploits the geometry of the process, which is independent of the workpiece material. The models are calibrated to a particular material using the well-established relationships between chip load and cutting forces, modified to take advantage of the characteristics of the drill point geometry. The models are validated independently for the cutting lips and the chisel edge for drilling both metals and fiber-reinforced composite materials for a wide range of machining conditions and drill geometry. While the cutting-lips model predictions agree well with the experimental data for both materials, only the chisel-edge model proposed for metals agrees well with the experimental data.

AB - In this paper models are developed to predict the thrust and the torque forces at the different regions of cutting on a drill. The mechanistic approach adopted to develop these models exploits the geometry of the process, which is independent of the workpiece material. The models are calibrated to a particular material using the well-established relationships between chip load and cutting forces, modified to take advantage of the characteristics of the drill point geometry. The models are validated independently for the cutting lips and the chisel edge for drilling both metals and fiber-reinforced composite materials for a wide range of machining conditions and drill geometry. While the cutting-lips model predictions agree well with the experimental data for both materials, only the chisel-edge model proposed for metals agrees well with the experimental data.

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Mechanistic approach to predicting the cutting forces in drilling: With application to fiber-reinforced composite materials

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