Electrolytic Plasma Hardening of 20GL Steel: Thermal Modeling and Experimental Characterization of Surface Modification
Rakhadilov B. Kurmangaliyev R. Shayakhmetov Y. Kussainov R. Maulit A. Kadyrbolat N.
August 2025Multidisciplinary Digital Publishing Institute (MDPI)
Applied Sciences (Switzerland)
2025#15Issue 15
This study investigates the thermal response and surface modification of low-carbon manganese-alloyed 20GL steel during electrolytic plasma hardening. The objective was to evaluate the feasibility of surface hardening 20GL steel—traditionally considered difficult to quench—by combining high-rate surface heating with rapid cooling in an electrolyte medium. To achieve this, a transient two-dimensional heat conduction model was developed to simulate temperature evolution in the steel sample under three voltage regimes. The model accounted for dynamic thermal properties and non-linear boundary conditions, focusing on temperature gradients across the thickness. Experimental temperature measurements were obtained using a K-type thermocouple embedded at a depth of 2 mm, with corrections for sensor inertia based on exponential response behavior. A comparison between simulation and experiment was conducted, focusing on peak temperatures, heating and cooling rates, and the effective thermal penetration depth. Microhardness profiling and metallographic examination confirmed surface strengthening and structural refinement, which intensified with increasing voltage. Importantly, the study identified a critical cooling rate threshold of approximately 50 °C/s required to initiate martensitic transformation in 20GL steel. These findings provide a foundation for future optimization of quenching strategies for low-carbon steels by offering insight into the interplay between thermal fluxes, surface kinetics, and process parameters.
boundary conditions , electrolytic plasma hardening , heat flux density , martensite , microhardness , numerical solution , thermal conductivity , voltage
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Plasma Science LLP, 070000, Ust-Kamenogorsk, Kazakhstan
Engineering Center “Strengthening Technologies and Coatings”, Shakarim University, Semey, 071412, Kazakhstan
Department of Digital Technologies in Mechanical Engineering and Logistics, Shakarim University, Semey, 071412, Kazakhstan
Plasma Science LLP
Engineering Center “Strengthening Technologies and Coatings”
Department of Digital Technologies in Mechanical Engineering and Logistics
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