Abstract

Accurate wear modeling has always been desired, but has also been difficult and elusive. Most useful wear models have relied on experimental calibration because the physical wear mechanisms are not fully understood. This is particularly true in machining, where contact stresses and temperatures can be extremely high. In machining, the two wear modes most frequently discussed are crater wear and flank wear. Flank wear receives much more attention because it is easier to measure and the mechanism of material loss is thought to be better understood for most machining situations. This work focuses on flank wear for the same reasons. In hard turning, tool life is relatively short and both crater wear and flank wear influence the cutting process substantially. Understanding the progression of flank wear at various cutting conditions is beneficial in itself, but the ability to predict this progression will be extremely valuable. This work addresses both. Experimental flank wear progression is shown for uncoated and ceramic-coated polycrystalline cubic boron nitride (PCBN) tools at a range of cutting conditions. These data are used to calibrate a proposed mechanical wear model that predicts the progression of flank wear and tool failure points based on the cutting speed, feed, and cutting depth. The model was validated by additional experiments, which show good agreement with the predictions.

1.
Konig
,
W.
, and
Neises
,
A.
1993, “
Wear Mechanisms of Ultra-Hard, Non-Metallic Cutting Materials
,”
Wear
0043-1648,
162–164
, pp.
12
21
.
2.
Luo
,
S. Y.
,
Liao
,
Y. S.
, and
Tsai
,
Y. Y.
, 1999, “
Wear Characteristics in Turning High Hardness Alloy Steel by Ceramic and CBN Tools
,”
J. Mater. Process. Technol.
0924-0136,
88
, pp.
114
121
.
3.
Barry
,
J.
, and
Byrne
,
G.
, 2001, “
Cutting Tool Wear in the Machining of Hardened Steels, Part I: Alumina∕TiC Cutting Tool Wear
,”
Wear
0043-1648,
247
, pp.
139
151
.
4.
Barry
,
J.
, and
Byrne
,
G.
, 2001, “
Cutting Tool Wear in the Machining of Hardened Steels, Part II: Cubic Boron Nitride Cutting Tool Wear
,”
Wear
0043-1648,
247
, pp.
139
151
.
5.
Zimmerman
,
M.
,
Lahres
,
M.
,
Viens
,
D. V.
, and
Laube
,
B. L.
, 1997, “
Investigation of the Wear of Cubic Boron Nitride Cutting Tools Using Auger Electron Spectroscopy and X-Ray Analysis by EPMA
,”
Wear
0043-1648,
209
, pp.
241
246
.
6.
Yamamoto
,
T.
,
Olsson
,
M.
, and
Hogmark
,
S.
, 1994, “
Three-Body Abrasive Wear of Ceramic Materials
,”
Wear
0043-1648,
174
, pp.
21
31
.
7.
Rabinowicz
,
E
, 1977, “
Abrasive Wear Resistance as a Material Test
,”
Lubr. Eng.
0024-7154,
33
(
7
), pp.
378
381
.
8.
Archard
,
J. F.
, 1953, “
Contact and Rubbing of Flat Surfaces
,”
J. Appl. Phys.
0021-8979,
24
, pp.
981
988
.
9.
Kennatey-Asibu
,
E.
, 1985, “
A transport-Diffusion Equation in Metal Cutting and Its Application to Analysis of the Rate of Flank Wear
,”
ASME J. Eng. Ind.
0022-0817,
107
, pp.
81
89
.
10.
Kramer
,
B. M.
, 1986, “
A Comprehensive Tool Wear Model
,”
CIRP Ann.
0007-8506,
35
(
1
), pp.
67
70
.
11.
Dawson
,
T. G.
, and
Kurfess
,
T. R.
, 2002, “
Machining Hardened Steel With Polycrystalline Cubic Boron Nitride
,” Ph.D. dissertation, Georgia Institute of Technology.
12.
Taylor
,
F. W.
, 1907, “
On the Art of Cutting Metals
,”
Trans. ASME
0097-6822,
28
pp.
31
279
.
You do not currently have access to this content.