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Effect of solution treatment on mechanical properties of cast AZ91-(Ca) alloys

Joong-Hwan Jun
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 1 | 265-269 | DOI: 10.24425/amm.2019.126247
Keywords AZ91 alloy calcium mechanical properties microstructure solution heat treatment
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Abstract

Effects of solution treatment on room temperature mechanical properties were studied in cast AZ91 (Mg-9%Al-1%Zn-0.2%Mn) and AZ91-0.5%Ca alloys. In as-cast state, the Ca addition contributed to the suppression of discontinuous β phase precipitation and the formation of Al2Ca phase. After solution treatment, the AZ91 alloy had only a small amount of Al8Mn5 particles, while β and Al2Ca phases were still present in the Ca-containing alloy. In as-cast state, the AZ91-0.5%Ca alloy showed better yield strength and hardness than the AZ91 alloy. The solution treatment increased the elongation in both alloys, which eventually led to the increase in ultimate tensile strength. The solution treatment resulted in a marked decrease in yield strength and hardness in the AZ91 alloy, whereas the decrements in those values were relatively negligible in the Ca-containing alloy due to the residual phases and solution hardening effect of Ca.

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Authors and Affiliations

Joong-Hwan Jun

Surfacing 24Cr-5Ni-2.5Mo Duplex Steel Castings by TIG

B. Kalandyk J. Kasińska A. Skrzypczyk
Archives of Foundry Engineering | 2018 | vol.18 | No 2 | DOI: 10.24425/122495
Keywords duplex cast steel surfacing TIG method solution heat treatment microstructure
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Abstract

This article discusses the influence of Tungsten Inert Gas (TIG) surfacing of duplex cast steel on its hardness and structure. The samples of 24Cr-5Ni-2.5Mo ferritic-austenitic cast steel were subjected to single-overlay processes with the use of solid wire having the chemical composition similar to that of the duplex cast steel. As a result of the surfacing, the welds were obtained that had no welding imperfections with a smooth transition to the base material. In the test without the heat treatment, directly below the fusion line, we observe a ferrite band with a width of approximately 200 m without visible austenite areas. Some of the samples were then solution treated (1060°C). Both variants, without and after solution heat treatment, were subjected to testing. Significant changes in the microstructure of the joint were observed after the heat treatment process (heat affected zone and weld microstructure changes). In both areas, an increase in the austenite volume fraction after solution heat treatment was observed. Changes in the microhardness of the ferrite in the HAZ area directly below the fusion line were also observed.
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Authors and Affiliations

B. Kalandyk
J. Kasińska
A. Skrzypczyk

The Effect of Work Hardening on the Structure and Hardness of Hadfield Steel

Damian Bańkowski Piotr S. Młynarczyk Wojciech P. Depczyński Kazimierz Bolanowski
Archives of Foundry Engineering | 2024 | vol. 24 | No 1 | 14-20 | DOI: 10.24425/afe.2024.149246
Keywords Manganese steel Hardness Modified Hadfield steel Solution heat treatment Computed tomography
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Abstract

The article aims to characterize Hadfield steel by analyzing its chemical composition, mechanical properties, and microstructure. The study focused on the twinning-induced work hardening of the alloy, which led to an increase in its hardness. The experimental data show that the material hardness at the surface improved considerably after solution heat treatment and work hardening, reaching more than 750 HV. By contrast, the hardness of the material core in the supersaturated condition was about 225 HV. The chemical and phase compositions of the material at the surface were compared with those of the core. The microstructural analysis of the steel revealed characteristic decarburization of the surface layer after solution heat treatment. The article also describes the effects of heat treatment on the properties and microstructure of Hadfield steel. The volumetric (qualitative) analysis of the computed tomography (CT) data of Hadfield steel subjected to heavy dynamic loading helped detect internal flaws, assess the material quality, and potentially prevent the structural failure or damage of the element tested.
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Bibliography

[1] Kalandyk, B., Tęcza, G., Zapała, R., Sobula, S. (2015). Cast high-manganese steel – the effect of microstructure on abrasive wear behaviour in miller test. Archives of Foundry Engineering. 15(2), 35-38. DOI: 10.1515/afe-2015-0033.
[2] Bartlett, L.N. & Avila, B.R. (2016). Grain refinement in lightweight advanced high-strength steel castings. International Journal of Metalcasting. 10, 401-420, DOI: 10.1007/s40962-016-0048-0.
[3] Guzman Fernandes, P.E. & Arruda, Santos, L. (2020). Effect of titanium and nitrogen inoculation on the microstructure, mechanical properties and abrasive wear resistance of Hadfield Steels. REM - International Engineering Journal. 73(5), 77-83. https://doi.org/10.1590/ 0370-44672019730023
[4] Chen, C., Lv, B., Feng, X., Zhang, F. & Beladi, H. (2018). Strain hardening and nanocrystallization behaviors in Hadfield steel subjected to surface severe plastic deformation. Materials Science and Engineering: A. 729, 178-184. DOI:10.1016/j.msea.2018.05.059.
[5] Chen, C., Zhang, F.C., Wang, F., Liu, H. & Yu, B.D. (2017). Efect of N+Cr alloying on the microstructures and tensile properties of Hadfield steel. Materials Science & Engineering. 679, 95-103. DOI:10.1016/j.msea.2016.09.106.
[6] Bolanowski, K. (2008). Wear of working elements made of Hadfield cast steel under industrial conditions. Problemy Eksploatacji. 2, 25-32.
[7] Tęcza, G., Sobula, S. (2014). Effect of heat treatment on change microstructure of cast high-manganese Hadfield steel with elevated chromium content. Archives of Foundry Engineering. 14(3), 67-70.
[8] Gürol, U., Karadeniz, E., Çoban, O., & Kurnaz, S.C. (2021). Casting properties of ASTM A128 Gr. E1 steel modified with Mn-alloying and titanium ladle treatment. China Foundry. 18, 199-206. https://doi.org/10.1007/s41230-021-1002-1
[9] Pribulová, A., Babic, J. & Baricová, D. (2011). Influence of Hadfield´s steel chemical composition on its mechanical properties. Chem. Listy. 105, 430-432.
[10] Przybyłowicz, K. (2008). Iron alloys engineering. Kielce: Wyd. Politechniki Świętokrzyskiej w Kielcach (in Polish).
[11] Stradomski, Z. (2001). On the explosive hardening of cast Hadfield steel. Proceedings of a Conference on Advanced Steel Casting Technologies. Kraków. 112-122. (in Polish).
[12] Cullity, B.D. (1964). Basics of X-ray diffraction. Warszawa: PWN. (in Polish).
[13] Bolanowski, K. (2013). The influence of the hardness of the surface layer on the abrasion resistance of Hadfield cast steel. Problemy Eksploatacji. 1, 127-139. (in Polish).
[14] Przybyłowicz, K. (2012). Metal Science. Warszawa: WNT. (in Polish).
[15] El Fawjhry, M.K. (2018). Feasibility of new ladle-treated Hadfield steel for mining purposes. International Journal of Minerals, Metallurgy and Materials. 25(3), 300, https://doi.org/10.1007/s12613-018-1573-z.
[16] Subramanyan, D.K, Swansieger, A.E. and Avery, H.S. (1990). Austenitic manganese steels. In ASM Metals Handbook. Vol. 1, 10th Ed. (p. 822-840). India: American Society of Metals, India.
[17] Zykova, A., Popova, N., Kalashnikov, M. & Kurzina, I. (2017). Fine structure and phase composition of Fe–14Mn–1.2C steel: influence of a modified mixture based on refractory metals. International Journal of Minerals, Metallurgy and Materials. 24(5), 523-529. DOI: 10.1007/s12613-017-1433-2.
[18] Vdovin, K.N., Feoktistov, N.A., Gorlenko, D.A. et al. (2019). Modification of High-Manganese Steel Castings with Titanium Carbonitride. Steel in Translation. 3, 147-151. https://doi.org/10.3103/S0967091219030136.
[19] Issagulov, A.Z., Akhmetov, A.B., Naboko, Ye.P., Kusainova, G.D. & Kuszhanova, A.A. (2016). The research of modification process of steel Hadfield integrated alloy ferroalumisilicocalcium (Fe-Al-Si-Сa/FASC). Metalurgija. 55(3), 333-336.
[20] Haakonsen, F., Solberg, J.K., Klevan, O. & Van der Eijk, C. (2011). Grain refinement of austenitic manganese steels. In AISTech - Iron and Steel Technology Conference Proceedings, 5-6 May 2011 (pp. 763-771). Indianapolis, USA.
[21] El Fawkhry, M.K. (2021). Modified hadfield steel for castings of high and low gouging applications. International Journal of Metalcasting. 15(2), 613-624. https://doi.org/10.1007/s40962-020-00492-5.
[22] EI Fawkhry, M.K., Fathy, A.M. and Eissa, M.M. (2015). New energy saving technology for producing Hadfield steel to high gouging applications. Steel Research International. 86(3), 223-230. https://doi.org/10.1002/srin.201300388.
[23] El-Fawkhry, M.K., Fathy, A.M., Eissa, M. & El-Faramway, H. (2014). Eliminating heat treatment of Hadfield steel in stress abrasion wear applications. International Journal of Metalcasting. 8, 29-36. DOI: 10.1007/BF03355569
[24] Sobula, S., Kraiński, S. (2021). Effect of SiZr modification on the microstructure and properties of high manganese cast steel. Archives of Foundry Engineering. 4, 82-86. ISSN (1897-3310).
[25] Zambrano, O.A., Tressia, G., Souza, R.M. (2020). Failure analysis of a crossing rail made of Hadfield steel after severe plastic deformation induced by wheel-rail interaction. Engineering Failure Analysis. 115, 104621. DOI: doi.org/10.1016/j.engfailanal.2020.104621.
[26] Wróbel, T., Bartocha, D., Jezierski, J., Kalandyk, B., Sobula, S., Tęcza, G., Kostrzewa, K., Feliks E. High-manganese alloy cast steel in applications for cast elements of railway infrastructure. In Współpraca 2023 : XXIX international scientific conference of Polish, Czech and Slovak foundrymen, 26-28 April 2023. Niepołomice.
[27] Młyński, M., Sobula, S., Furgał, G. (2001). Economic aspects of the oxygen-recovery melts of Hadfield cast steel in the Foundry of Metalodlew S.A. Przegląd Odlewnictwa. 51(11), 382-384. (in Polish).
[28] Wróbel, T., Bartocha, D., Jezierski, J., Sobula, S., Kostrzewa K., Feliks E. (2023). High-manganese alloy cast steel used for cast elements of railway infrastructure. Stal, Metale & Nowe Technologie. 1-2, 30-34. (in Polish).
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Authors and Affiliations

Damian Bańkowski
1
ORCID: ORCID
Piotr S. Młynarczyk
1
ORCID: ORCID
Wojciech P. Depczyński
1
ORCID: ORCID
Kazimierz Bolanowski
1
ORCID: ORCID
  1. Kielce University of Technology, Poland

Effect of Hot Isostatic Pressing and Solution Heat Treatment on the Microstructure and Mechanical Properties of Ti-6Al-4V Alloy Manufactured by Selective Laser Melting

Dohoon Lee Tae-Yeong So Ha-Young Yu Gyunsub Kim Eushin Moon Se-Hyun Ko
Archives of Metallurgy and Materials | 2024 | vol. 69 | No 1 | 135-139 | DOI: 10.24425/amm.2024.147801
Keywords Selective Laser Melting (SLM) hot isostatic pressing Solution heat treatment Ti-6Al-4V texture
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Abstract

A powder-bed-based additive manufacturing process called electron beam melting (EBM) is defined by high temperature gradients during solidification, which produces an extremely fine microstructure compared to the traditional cast material. However, porosity and segregation defects are still present on a smaller scale which may lead to a reduction in mechanical properties. It is important to have a better knowledge of the influence of post-fabrication treatments on the microstructure and mechanical characteristics before the use of additive manufacturing parts in specific applications. In this study, the effects of solution heat treatment (SHT) and hot isostatic pressing (HIP) on the microstructure and mechanical properties of Ti-6Al-4V alloy fabricated by the EBM process have been investigated. The SHT and HIP treatments can significantly improve the ductility of EBM Ti-6Al-4V due to the coarsening of α laths and the formation of β grains.
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Authors and Affiliations

Dohoon Lee
1
ORCID: ORCID
Tae-Yeong So
1
ORCID: ORCID
Ha-Young Yu
1
ORCID: ORCID
Gyunsub Kim
2
ORCID: ORCID
Eushin Moon
2
ORCID: ORCID
Se-Hyun Ko
1
ORCID: ORCID
  1. Korea Institute of Industrial Technology (KITECH), Industrial Materials Processing R&D Department, 156, Gaetbeol-ro, Yeonsu-gu, Incheon 406-840, Republic of Korea
  2. Huneed Technologies, Incheon, Republic of Korea

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