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TECHNICAL PAPERS

Mechanical Properties of Hardened AISI 52100 Steel in Hard Machining Processes

[+] Author and Article Information
Y. B. Guo, C. R. Liu

School of Industrial Engineering, Purdue University, West Lafayette, IN 47907

J. Manuf. Sci. Eng 124(1), 1-9 (Apr 01, 2001) (9 pages) doi:10.1115/1.1413775 History: Received August 01, 1999; Revised April 01, 2001
Copyright © 2002 by ASME
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References

Konig,  W., Klinger,  M., and Link,  R., 1990, “Machining Hard Materials with Geometrically Defined Cutting Edges-Field of Applications and Limitations,” CIRP Ann., 39/1, pp. 61–64.
Toenshoff,  H. K., Wobker,  H. G., and Brandt,  D., 1995, “Hard Turning—Influences on the Workpiece Properties,” Transactions of NAMRI/SME, Vol.XXIII, pp. 215–220.
Liu,  C. R., and Mittal,  S., 1996, “Single-Step Superfinish Hard Machining: Feasibility and Feasible Cutting Conditions,” J. of Robotics & Computer-Integrated Manufacturing, 12, No. 1, pp. 15–27.
van Luttervelt,  C. A., Childs,  T. H. C., Jawahir,  I. S., Klocke,  F., and Venuvinod,  P. K., 1998, “Present Situation and Future Trends in Modeling of Machining Operations—Progress Report of the CIRP Working Group ’Modeling of Machining Operations,” CIRP Ann., 47/2, pp. 587–626.
Olxey, P. L. B., 1989, The Mechanics of Machining, Ellis Horwood, Chichester.
MacGregor,  C. F., and Fisher,  J. C., 1946, ASME J. Appl. Mech., 13, pp. 11–16.
Stevenson,  R., and Stephenson,  D. A., 1995, “The Mechanical Behavior of Zinc During Metal Cutting,” J. Eng. Mat. Tech., 117, pp. 172–178.
Stevenson,  R., 1997, “Study on the Correlation of Workpiece Mechanical Properties from Compression and Cutting Tests,” J. of Machining Science and Technology, 1(1), pp. 67–79.
Spaans, C., 1971, “The Fundamentals of Three-Dimensional Chip Curl, Chip Breaking and Chip Control,” Ph.D. Dissertation, Delft University of Technology.
Stevenson, M. G., and Oxley, P. L. B., 1975, “Torsional Hopkinson Bar Tests to Measure Stress-Strain Properties Relevant to Machining and High Speed Forming,” North America Metalwork Res. Conf., 3rd Proc., Pittsburgh, PA, May 5–7, pp. 291–304.
Shirakashi,  T., Maekawa,  K., and Usui,  E., 1983, “Flow Stress of Low Carbon Steel at High Temperature and Strain Rate,” Bull. Jpn. Soc. Precis. Eng., 17, No. 3, pp. 161–172.
Yoshino,  M., and Shirakashi,  T., 1997, “Flow-Stress Equation Including Effects of Strain Rate and Temperature History,” Int. J. Mech. Sci., 39, No. 12, pp. 1345–1362.
Hibbit, Karlsson, and Sorenson, Inc., 1998, ABAQUS/Explicit User’s Manual, ver. 5.8, Providence, RI.
Reddy, J. N., 1993, An Introduction to the Finite Element Method, McGraw-Hill, Inc.
Luttervelt,  C. A., and Pekelharing,  A. J., 1977, “The Split Shear-Zone-Mechanisms of Chip Segmentation,” CIRP Ann., 26/1, p. 33.
Nakayama,  K., Arai,  M., and Kanda,  T., 1988, “Machining Characteristics of Hard Materials,” Annals of the CIRP, 37/1, pp. 89–92.
Elbestawi,  M. A., Srivastava,  A. K., and El-Wardany,  T. I., 1996, “A Model for Chip Formation During Machining of Hardened Steel,” CIRP Ann., 45/1, pp. 71–76.
Vyas,  A., and Shaw,  M. C., 1998, “The Mechanism of Chip Formation with Hard Turning Steel,” CIRP Ann., 47/1, pp. 77–82.
Toulaukian, Y. S., 1967, Thermophysical Properties of High Temperature Solid Materials, Vol. 3, Macmillan, New York.
Gupta,  V., Bastias,  P., Hahn,  G. T., and Rubin,  C. A., 1993, “Elastio-plastic Finite Element Analysis of 2D Rolling-plus-sliding Contact with Temperature-dependent Bearing Steel Material Properties,” Wear, 169, pp. 251–256.
Maekawa,  K., Shirakashi,  T., and Obikawa,  T., 1996, “Recent Progress of Computer Aided Simulation of Chip Flow and Tool Damage in Metal Machining,” Proc. Instn. Mech. Engrs., 210, pp. 233–242.
Obikawa,  S. H., Shirakashi,  T., and Usui,  E., 1997, “Application of Computational Machining Method to Discontinuous Chip Formation,” ASME J. Manuf. Sci. Eng., 119, pp. 667–674.
Guo,  Y. B., and Dornfeld,  D. A., 1998, “Finite Element Analysis of Drilling Burr Minimization with a Backup Material,” Trans. of NAMRI/SME, Vol. XXVI, pp. 207–211.

Figures

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Specimen geometry and dimension
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Experimental setup schematic of tensile testing at elevated temperature
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at room temperature
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at 200°C
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at 400°C
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at 600°C
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at 800°C
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The engineering stress-strain curve for AISI 52100 steel (62 HRC) at 1000°C
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Flow stress vs. velocity-modified temperature Tmod
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Chip formation in hard facing of cutting
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Cutting forces from FEM prediction and experiment of cutting condition 1
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Cutting forces from FEM prediction and experiment of cutting condition 2
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Flow chart to estimate the flow stress and Tmod from cutting tests

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