The identification of tool/chip interface temperatures from remote sensor measurements is a steady inverse heat transfer problem that arises in online machine tool monitoring. In a previous paper we developed a set of inverse approaches, vector projection inverse methods, specifically for this problem. These methods rely on two types of sensor measurements: temperatures and heat fluxes. However, because of the extreme ill-conditioning of the tool configuration we studied previously, only a very limited amount of information could be obtained using any of the inverse approaches examined. In an effort to understand the impact of physical parameters on the conditioning of the problem we examined two modifications to the simulated cutting tool: we increased the thermal conductivity of the tool insert, and we reduced the thickness of the tool insert. Inverse solutions were computed on both configurations with all methods for two temperature profiles and various noise levels. The estimated tool/chip interface temperature for the high conductivity tool showed no improvement compared to the original configuration, since the temperature profiles on the sensor surface were unchanged. However, for the thinner tool, the estimated temperatures were substantially more accurate than with the original configuration. With this thinner tool configuration, an optimal set of four sensors could be used to estimate these temperatures at the tool/chip interface to within a few degrees, even with noisy sensor data.

1.
Yen
,
D.
, and
Wright
,
P.
,
1986
, “
A Remote Temperature Sensing Technique for Estimating the Cutting Interface Temperature Distribution
,”
ASME J. Eng. Ind.
,
108
, pp.
252
263
.
2.
Chow
,
J.
, and
Wright
,
P.
,
1988
, “
On-Line Estimation of Tool/Chip Interface Temperatures for a Turning Operation
,”
ASME J. Heat Transfer
,
110
, pp.
56
64
.
3.
Xu
,
W.
,
Genin
,
J.
, and
Dong
,
Q.
,
1997
, “
Inverse Method to Predict Temperature and Heat Flux Distribution in a Cutting Tool
,”
ASME J. Heat Transfer
,
119
, pp.
655
659
.
4.
Stephenson
,
D.
,
1991
, “
An Inverse Method for Investigating Deformation Zone Temperatures in Metal Cutting
,”
ASME J. Eng. Ind.
,
113
, pp.
129
136
.
5.
Lipman
,
M.
,
Nevis
,
B.
, and
Kane
,
G.
,
1967
, “
A Remote Sensor Method for Determining Average Tool-Chip Interface Temperatures in Metal Cutting
,”
ASME J. Ind.
,
89
, pp.
333
338
.
6.
Lin
,
J.
,
Lee
,
S.
, and
Weng
,
C.
,
1992
, “
Estimation of Cutting Temperature in High Speed Machining
,”
ASME J. Eng. Mater. Technol.
,
114
, pp.
289
296
.
7.
Shaik
,
A.
,
Raman
,
S.
,
Civan
,
F.
, and
Cohen
,
P.
,
1995
, “
A New Forward Temperature Estimator for Remote Thermocouple Sensing in Machining
,”
Int. J. Mech. Sci.
,
37
, pp.
511
526
.
8.
Olson
,
L.
, and
Throne
,
R.
,
2001
, “
Estimation of Tool/Chip Interface Temperatures for On-Line Tool Monitoring: An Inverse Problem Approach
,”
Inverse Probl. Eng.
,
9
, pp.
367
388
.
9.
Throne
,
R. D.
, and
Olson
,
L. G.
,
2000
, “
Fusion of Body Surface Potential and Body Surface Laplacian Signals for Electrocardiographic Imaging
,”
IEEE Trans. Biomed. Eng.
,
47
, pp.
452
462
.
10.
Throne
,
R. D.
,
Olson
,
L. G.
, and
Hrabik
,
T. J.
,
1999
, “
A Comparison of Higher-Order Generalized Eigensystem Techniques and Tikhonov Regularization for the Inverse Problem of Electrocardiography
,”
Inverse Probl. Eng.
,
7
, pp.
143
193
.
11.
Throne
,
R. D.
,
Olson
,
L. G.
,
Hrabik
,
T. J.
, and
Windle
,
J. R.
,
1997
, “
Generalized Eigensystem Techniques for the Inverse Problem of Electrocardiography Applied to a Realistic Heart-Torso Geometry
,”
IEEE Trans. Biomed. Eng.
,
44
, pp.
447
454
.
12.
Olson
,
L. G.
,
Throne
,
R. D.
, and
Windle
,
J. R.
,
1997
, “
Performance of Generalized Eigensystem and Truncated Singular Value Decomposition Methods for the Inverse Problem of Electrocardiography
,”
Inverse Probl. Eng.
,
5
, pp.
239
277
.
13.
Olson
,
L.
, and
Throne
,
R.
,
1995
, “
Computational Issues Arising in Multidimensional Elliptic Inverse Problems: The Inverse Problem of Electrocardiography
,”
Eng. Comput.
,
12
(
4
), pp.
343
356
.
14.
Throne
,
R. D.
, and
Olson
,
L. G.
,
1995
, “
The Effects of Errors in Assumed Conductivities and Geometry on Numerical Solutions to the Inverse Problem of Electrocardiography
,”
IEEE Trans. Biomed. Eng.
,
42
, pp.
1192
1200
.
15.
Throne
,
R.
, and
Olson
,
L.
,
1994
, “
A Generalized Eigensystem Approach to the Inverse Problem of Electrocardiography
,”
IEEE Trans. Biomed. Eng.
,
41
, pp.
592
600
.
16.
“OMEGA Engineering Website: HFS Series Heat Flux Sensor,” http://www.omega.com, 2003.
17.
Frolick
,
G.
,
2001
, “
Thin Film Heat Flux Sensor
,”
Aerospace Technology Innovation
,
9
(
1
),
January/February
January/February
.
18.
Ostafiev
,
V.
,
Kharkevich
,
A.
,
Weinert
,
K.
, and
Ostafiev
,
S.
,
1999
, “
Tool Heat Transfer in Orthogonal Metal Cutting
,”
ASME J. Manuf. Sci. Eng.
,
121
, pp.
541
549
.
19.
Stevenson
,
M. G.
,
Wright
,
P. K.
, and
Chow
,
J. G.
,
1983
, “
Further Developments in Applying the Finite Element Method to the Calculation of Temperature Distributions in Machining and Comparisons With Experiment
,”
ASME J. Eng. Ind.
,
105
, pp.
149
154
.
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