Experimental and Computational Study of the Quenching of Carbon Steel

An investigation of the quenching of 1080 carbon steel cylinders has been carried out to determine the validity of a quenching process model for carbon steels. The process model included a description of the austenite-pearlite and austenite-martensite transformations in carbon steels, temperature-dependent material properties, and an elastic-plastic stress analysis. The model was simulated using the finite element method (FEM). An experimental study of the quenching of 1080 steel cylinders in water and two types of polymeric quenchants has also been carried out. The temperatures at three points within the cylinder during quenching were measured using thermocouples. The hardness and residual stress distributions along a cross-section of the quenched cylinders were determined using a Rockwell hardness test and an X-ray diffraction technique, respectively. The temperature-time histories, residual stress, and hardness distributions predicted from the FEM simulation of the quenching model were found to be in good agreement with the corresponding measurements. The quenching process simulation described in the study appears to be a promising tool for the design of heat-treatment process parameters for carbon steels.

[1]  M. M. Chaudhri,et al.  Indentation cracking in soda-lime glass and Ni-Zn ferrite under Knoop and conical indenters and residual stress measurements , 1993 .

[2]  S. Chandrasekar,et al.  An Efficient 2D Finite Element Procedure for the Quenching Analysis With Phase Change , 1993 .

[3]  Srinivasan Chandrasekar,et al.  Finite-element simulation of induction heat treatment , 1992 .

[4]  B. Buchmayr,et al.  Modeling of the temperature field, transformation behavior, hardness and mechanical response of low alloy steels during cooling from the austenite region , 1990 .

[5]  S. Sjöström,et al.  Coupled temperature, stress, phase transformation calculation , 1987, Metallurgical and Materials Transactions A.

[6]  A. Simon,et al.  Mathematical model coupling phase transformation and temperature evolution during quenching of steels , 1985 .

[7]  M. R. James,et al.  Factors Influencing Residual Surface Stresses due to a Stress‐Induced Phase Bansformation , 1983 .

[8]  Franz G. Rammerstorfer,et al.  On thermo-elastic-plastic analysis of heat-treatment processes including creep and phase changes , 1981 .

[9]  Tatsuo Inoue,et al.  Description of transformation kinetics, heat conduction and elastic-plastic stress in the course of quenching and tempering of some steels , 1981 .

[10]  J. K. Brimacombe,et al.  Mathematical model of heat flow and austenite-pearlite transformation in eutectoid carbon steel rods for wire , 1981 .

[11]  M. R. James,et al.  The Measurement of Residual Stresses by X-Ray Diffraction Techniques , 1980 .

[12]  M. Khoshgoftaar,et al.  Finite element formulation and solution of nonlinear heat transfer , 1979 .

[13]  Tatsuo Inoue,et al.  An elastic-plastic stress analysis of quenching when considering a transformation , 1975 .

[14]  D. P. Koistinen,et al.  A general equation prescribing the extent of the austenite-martensite transformation in pure iron-carbon alloys and plain carbon steels , 1959 .

[15]  M. Avrami Kinetics of Phase Change. II Transformation‐Time Relations for Random Distribution of Nuclei , 1940 .

[16]  M. Avrami,et al.  Kinetics of Phase Change 2 , 1940 .

[17]  M. Avrami Kinetics of Phase Change. I General Theory , 1939 .

[18]  W. A. Johnson Reaction Kinetics in Processes of Nucleation and Growth , 1939 .