The Design of a System for the Induction Hardening of Steels Using Simulation Parameters

Stević, Zoran; Dimitrijević, Stevan P.; Stević, Miša; Stolić, Predrag; Petrović, Sanja J.; Radivojević, Milan; Radovanović, Ilija

doi:10.3390/app132011432

Applied Sciences

2023

DOI: 10.3390/app132011432

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The Design of a System for the Induction Hardening of Steels Using Simulation Parameters

Zoran Stević,

Stevan P. Dimitrijević,

Miša Stević

et al.

Abstract: This paper presents the development of a piece of induction hardening equipment based on the foundations of the design, starting from zero. It was intended for steels in general, and was tested on unalloyed low- and medium-carbon steels, whereas the results for EN 1C60 steel are shown in this study. The EN 1C60 steel showed average results, and was chosen as a representative of a wider group of engineering steels. The main objective of this work was to develop a flexible system for mild steel hardening that ca… Show more

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2024

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Cited by 3 publications

References 31 publications

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A comprehensive review of metal laser hardening: mechanism, process, and applications

Wang,

Xia,

Liu

et al. 2024

Int J Adv Manuf Technol

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A comprehensive review of metal laser hardening: mechanism, process, and applications

Wang,

Xia,

Liu

et al. 2024

Int J Adv Manuf Technol

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Investigation of Surface Hardness and Microstructural Changes in S45C Carbon Steel Cylinders Through Arc Quenching

Son Minh,

Nguyen,

Nguyen

et al. 2024

Metals

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Arc quenching has many advantages, including generating large amounts of heat in a short time, a self-quenching ability, and simple equipment. The electric arc energy from a TIG welding machine was used to modify the surface properties of S45C Carbon Steel Cylinders. The study focuses on the impact of arc length, current intensity, travel speed, gas flow rate, heating angle, and pulse on surface hardness after arc quenching an S45C steel tube with a cylinder surface. The study found that the hardness reduces from 45.1 HRC to 41.2 HRC as the current intensity increases from 125 A to 140 A. According to Taguchi’s results, the ranking of factors which have the greatest impact on surface hardness are pulse time, travel speed, intensity, gas flow rate, arc length, and heating angle. The pulse time has the highest impact because it directly influences the heating input, followed by the travel speed. Arc length and heating angle, on the other hand, have the least effect. The base metal, heat-affected area, and hardened area are the three distinct areas that make up the microstructure structure. After the arc quenching process, the case hardening depth is represented by the heat-affected zone at 1536 μm. A highly colored residual austenite and a needle-shaped martensite phase make up the hardened region. The hardened region is 1200 μm thick and has a hardness of more than 300 HV0.3. The study’s findings may improve the application and understanding of the arc quenching treatment procedure in the industrial sector.

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Modeling and Simulation of the Induction Hardening Process: Evaluation of Gear Deformations and Parameter Optimization

Pinheiro,

Junio,

Gonçalves

et al. 2024

Processes

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This study aimed to analyze and optimize the thermal induction hardening process applied to toothed transmission gears, focusing on thermal aspects, structural deformation, and topology optimization, while exploring the feasibility of various materials and operating conditions. The research simulated thermal and deformation behavior using a computer model, comparing results with experimental data through the Ansys® platform 2022 R1. The methodology encompassed thermal and deformation analyses, topology optimization to identify removable regions without compromising part integrity, and a sensitivity study to evaluate the different materials and operating conditions. This study validates the precision of computational models in predicting thermal and deformation behavior in toothed gears under thermal induction hardening, introducing topology optimizations and alternative materials, and providing novel perspectives for the more efficient and cost-effective manufacturing of these components. Comparative thermal analysis revealed a maximum relative error of less than 6% between temperatures from the computer model and experimental results, while deformation comparisons exhibited a maximum relative error of less than 7%, affirming the simulation model’s accuracy in predicting and managing deformations within acceptable thresholds. Topology optimization successfully pinpointed removable regions without compromising structural integrity, enabling the production of lighter and more economical devices. Future endeavors should concentrate on additional tests to verify the feasibility of reducing power and cooling temperature without compromising product specifications. Furthermore, it is advisable to explore alternative materials and apply the developed methodology in diverse industrial settings to generalize the findings and amplify the impact of the proposed optimizations.

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The Design of a System for the Induction Hardening of Steels Using Simulation Parameters

Cited by 3 publications

References 31 publications

A comprehensive review of metal laser hardening: mechanism, process, and applications

A comprehensive review of metal laser hardening: mechanism, process, and applications

Investigation of Surface Hardness and Microstructural Changes in S45C Carbon Steel Cylinders Through Arc Quenching

Modeling and Simulation of the Induction Hardening Process: Evaluation of Gear Deformations and Parameter Optimization

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