Conform™ extrusion is a very versatile manufacturing process enabling the production of a wide range of extruded profiles. It is critical to maintain a precise predefined wheel-tooling gap for the efficient running of the Conform extrusion process and to maintain high product quality. However, this is a challenging task due to the hostile environment, high operating temperatures, and required accuracy. An accurate high-temperature gap measurement system for Conform extrusion machinery, using a capacitive sensing system, is developed in this study. The sensor is implemented in a copper Conform extrusion machine, and experimental results are presented, providing for the first time a detailed view of Conform Extrusion gap behavior during production. It is shown that the proposed gap-sensing and control system results in a number of advantages, including reduced machine setup times, reduced flash (waste) rates, and on-line monitoring and control of gap size. The research is carried out in collaboration with Holton Machinery Ltd., a leading manufacturer of Conform Extrusion machinery.

Issue Section:
Technical Papers
Keywords:
copper, extrusion, capacitive sensors, distance measurement, displacement control, three-term control, wheels, machine tools, metallurgical industries, Conform™ Extrusion, High Temperature Gap Measurement, Capacitive Sensors
Topics:
Extruding, Machinery, Sensors, Wheels, Tooling
1.
Etherington, C., 1973, “CONFORM—A New Concept of Continuous Forming of Metals,” ASME No. 73, WA/PT2.
2.
Maddock, B., 1984, “Introduction and Information of Conform,” Northern Non-Ferrous Wire Drawing Association Annual Meeting, 4th and 5th, Malmo, Sweden.
3.
Etherington, C., and Slater, H. K., 1984, “The Extrusion of Aluminum and Its Alloys by the CONFORM Process,” Proc. of Third Int. Aluminum Extrusion Technology Seminar, Vol. 2, pp. 31–38, Atherton, Aluminum Extruders Council and the Aluminum Association.
4.
Slater, H. K., and Coon, P. M., 1988, “Aluminum Extrusion by Conform—An Update on Development Experience at the Springfields Laboratories of the UK Atomic Energy Authority,” Proc. of Fourth Int. Aluminum Extrusion Technology Seminar, Aluminum Extruders Council and the Aluminum Association, Chicago, Vol. 2, pp. 525–532.
5.
Bridewater, M., and Maddock, B., 1992, “New Developments in Conform Technology for Continuous Extrusion,” Proc. of Fifth Int. Aluminum Extrusion Technology Seminar, Chicago, Aluminum Extruders Council and the Aluminum Association, Vol. 1, pp. 413–419.
6.
Green
,
D.
,
1972
, “
Continuous Extrusion-Forming of Wire Sections
,”
J. Inst. Met.
,
100
, pp.
295
300
.
1.
Etherington
,
C.
,
1977
, “
The UKAEA Conform Method of Continuous Extrusion Forming
,”
Wire Ind.
,
1
(
2
), pp.
85
89
;
2.
1977
2
(
3
), pp.
161
169
.
1.
Gorokhov
,
Y. V.
,
Sergeev
,
V. M.
,
Gilevich
,
F. S.
, and
Kornilov
,
V. N.
,
1987
, “
Force Parameters of Continuous Metal Pressing by Conform Method
,”
Tsvetnye Met.
,
4
, pp.
73
75
.
2.
Carr, N., Ahmad, H. Y., and Clode, M. P., 1996, “Simulation and Analysis of Deformation in Conform Extrusion,” Proc. of the Sixth Int. Aluminum Extrusion Technology Seminar, Vol. 11, pp. 413–419, Aluminum Extruders Council and the Aluminum Association, Chicago.
3.
Im
,
Y. T.
,
Kang
,
S. H.
, and
Cheon
,
J. S.
,
2002
, “
Finite Element Investigation of Friction Condition in a Backward Extrusion of Aluminum Alloy
,”
ASME J. Manuf. Sci. Eng.
,
125
(
2
), pp.
378
383
.
4.
Gordon
,
W. A.
,
Van Tyne
,
C. J.
, and
Sriram
,
S.
,
2002
, “
Extrusion Through Spherical Dies—An Upper Bound Analysis
,”
ASME J. Manuf. Sci. Eng.
,
124
(
1
), pp.
92
97
.
5.
Byon
,
S. M.
, and
Hwang
,
S. M.
,
1997
, “
Die Shape Optimal Design in Bimetal Extrusion by the Finite Element Method
,”
ASME J. Manuf. Sci. Eng.
,
119
(
2
), pp.
143
150
.
6.
Kim
,
Y. H.
,
Cho
,
J. R.
,
Jeong
,
H. S.
,
Kim
,
K. S.
, and
Yoon
,
S. S.
,
1998
, “
A Study on Optimal Design for CONFORM Process
,”
J. Mater. Process. Technol.
,
80
–81, pp.
671
675
.
7.
Kim
,
Y. H.
,
Cho
,
J. R.
,
Kim
,
K. S.
,
Jeong
,
H. S.
, and
Yoon
,
S. S.
,
2000
, “
A Study of the Application of Upper Bound Method to the CONFORM Process
,”
J. Mater. Process. Technol.
,
97
, pp.
153
157
.
8.
Maddock, B., 2000, “The Structure and Development of a Computer Model to Simulate the Conform Process,” Proc. of Seventh Int. Aluminum Extrusion Technology Seminar, Vol. 1, pp. 519–531, Chicago, USA, Aluminum Extruders Council and the Aluminum Association.
9.
Velay, X., and Sheppard, T., 2000, “Plain Strain and Three-Dimensional Coupled Thermomechanical Simulation of the Conform™ Process,” Proc. of Seventh International Aluminum Extrusion Technology Seminar, Vol. 1, pp. 505–515, Chicago, USA, Aluminum Extruders Council and the Aluminum Association.
10.
Outokumpu Copper Oy, 1997, “Method for the Continuous Extrusion of Metals,” UK Patent No. 9704202.2, Feb. 28.
11.
Holton Machinery Ltd, 1988, “Continuous Extrusion Using Active Shoe Positioning,” UK Patent No. 9825106.9, Nov. 16.
12.
Khawaja, K., Maddock, B., Smith, M., Seneviratne, L., and Clode, M., “Automatic Control of the Conform™ Extrusion Machine Using Air Gauge Sensors,” Submitted to IEEE/ASME Transactions on Mechatronic.
13.
Foster, R., 1989, “Linear Capacitive Reactance Sensors for Industrial Applications,” SAE Technical Paper Series, Paper no. 890974, 40th Annual Earthmoving Industry Conference, Peoria.
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