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The sensitivity of the Koistinen-Marburger (KM) model parameters governing the martensitic transformation kinetics in SAE 9254 spring steel was systematically investigated using a finite element approach. A transient thermal model was developed in ANSYS Workbench to simulate the quenching of cylindrical specimens under two industrially relevant cooling protocols: single-step cooling at 40 °C/s) and two-step cooling (20 °C/s followed by 1 °C/s), where the slower second stage was designed to promote bainite formation prior to the martensitic transformation. The simulated temperature-time profiles were validated against published dilatometric data, with deviations remaining below 10 %. A structured parametric sensitivity analysis was carried out by varying the fitted transformation start temperature Tₖₘ by ±10 °C and the rate parameter α by approximately ±10 %, across austenitizing temperatures ranging from 850 to 1050 °C. The results demonstrate that Tₖₘ governs the onset of the martensitic transformation, shifting the martensite fraction curve along the temperature axis without altering its shape. In contrast, α controls the steepness and rate of transformation without affecting the initiation temperature. In all cases examined, the final martensite fraction exceeded 0.99, indicating a low sensitivity of transformation completeness within the parameter ranges investigated. A clear distinction between the two cooling strategies was observed: α values under two-step cooling (0.0499-0.0985 K⁻¹) were considerably higher than those under single-step cooling (0.0283-0.0443 K⁻¹), which can be attributed to the reduced stability of the remaining austenite following bainite formation. These findings confirm the decoupled roles of the KM parameters and their dependence on the prior thermal history. The proposed computational framework provides an efficient tool for evaluating the sensitivity of transformation parameters and supporting the optimisation of industrial heat treatment processes.
Keywords: Martensitic transformation, Koistinen-Marburger model, sensitivity analysis, SAE 9254, spring steel, finite element simulation, ANSYS, quenching, bainite, heat treatment© This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.