Affiliation:
1. Process Engineering Center—Fuel Systems, Cummins Engine Company, Inc., Columbus, IN 47202-3005
Abstract
The development and implementation of a plane-strain finite element method for the simulation of orthogonal metal cutting with continuous chip formation are presented. Detailed work-material modeling, including the effects of elasticity, viscoplasticity, temperature, large strain, and high strain-rate, is used to simulate the material deformation during the cutting process. The unbalanced force reduction method and sticking-sliding friction behavior are implemented to analyze the cutting process. The deformation of the finite element mesh and comparisons of residual stress distributions with X-ray diffraction measurements are presented. Simulation results along the primary and secondary deformation zones and under the cut surface, e.g., the normal and shear stresses, temperature, strain-rate, etc., are presented revealing insight into the metal cutting process.
Reference24 articles.
1. Boothroyd, G., and Knight, W. A., 1989, Fundamentals of Machining and Machine Tools, 2nd Ed., Marcel Dekker, NY.
2. Carroll
J. T.
, and StrenkowskiJ. S., 1988, “Finite Element Models of Orthogonal Cutting with Application to Single Point Diamond Turning,” Int. J. Mech. Sci., Vol. 30, pp. 899–920.
3. Eldridge
K. F.
, DillonO. W., and LuW. Y., 1991, “Thermo-Viscoplastic Finite Element Modeling of Machining Under Various Cutting Conditions,” Trans. NAMRC, XIX, pp. 162–169.
4. Hastings
W. F.
, MathewP., and OxleyP. L. B., 1980, “A Machining Theory for Predicting Chip Geometry, Cutting Forces, etc., from Work Material Properties and Cutting Conditions,” Proc. Royal Soc. London, Ser. A, Vol. 371, pp. 569–587.
5. Iwata
K.
, OsakadaK., and TerasakaY., 1984, “Process Modeling of Orthogonal Cutting by the Rigid-Plastic Finite Element Method,” ASME Journal of Engineering Materials and Technology, Vol. 106, pp. 132–138.
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