Electromagnetic Shielding Properties of Pack Borided MirraxTM Steel
Yıl 2021,
, 1304 - 1312, 31.12.2021
İbrahim Altınsoy
Öz
In this study, it was aimed to investigate the electromagnetic interference shielding (EMI-SE) as well as some physical and mechanical properties of pack borided Mirrax tool steel. Boriding process was carried out at 900, 950 and 1000°C for 2, 5,8h, respectively. Optical images showed that borides layer have smooth morphology and flat interface with matrix. XRD analysis revealed that main phases in the layer were FeB and Fe2B. Intensity of FeB phases increased with increment of process temperature and time. Depending on process time and temperature the thickness of borides layer was ranged from 10 mm to 87.80 um. Microhardness of layer was between 1700 and 2400 HV. EMI-SE measurements conducted within Ku band (12-20 GHz) indicated that EMI-SE efficiency increased by increasing of process time and temperature and it was ranged from 52dB to 75dB. It is possible to claim that borided Mirrax steel performed good EMI-SE and when boriding time reached to 5h, remarkable EMI-SE (electromagnetic interference shielding) (over 60dB) was observed on the sample borided even at 900°C.
Teşekkür
I would like to express my deepest thank to Prof. Dr. Cuma Bindal of Sakarya University for his invaluable supports. Special thank to Namık Kemal Akyürek and Muhammet Baybars Gökcan for helping experimental studies.
Kaynakça
- [1] N. Maruthi, M. Faisal and N. Raghavendra, “Conducting polymer based composites as efficient EMI shielding materials: A comprehensive review and future prospects,” Synthetic Metals, vol. 272, pp. 1-20, 2021.
- [2] G-H. Lim, N. Kwon, E. Han, S. Bok and S-E. Lee S, “Flexible Nanoporous Silver Membranes with Unprecedented High Effectiveness for Electromagnetic Interference Shielding,” Journal of Industrial and Engineering Chemistry, Article in press, 2020.
- [3] H. Liu, S. Wou, C. You, N. Tian, Y. Li and N. Chopra, “Recent progress in morphological engineering of carbon materials for electromagnetic interference shielding,” Carbon, vol. 172, pp. 569–596, 2021.
- [4] H. Zhang, B. Zhao, F-Z. Dai, H. Xiang and Z. Zhang, “(Cr0.2Mn0.2Fe0.2Co0.2Mo0.2)B: A novel high-entropy monoboride withgood electromagnetic interference shielding performance in K-band,” Journal of Materials Science & Technology, vol. 77, pp. 58-65, 2021.
- [5] N. L. Perrusquia, M. A. Doñu Ruiz, C.R. Torres San Miguel, G.J. Pérez Mendoza, J.V. Cortes Suarez and A. Juanico Loran, “Evaluation of properties in steel with boride coatings under hydrogen,” Surface & Coatings Technology, vol. 377, pp. 1-9, 2019.
- [6] G. K. Sireli, A. S. Bora and S. Timur, “Evaluating the mechanical behavior of electrochemically borided low carbon steel,” Surface & Coatings Technology, vol. 381, pp. 1-10, 2020.
- [7] M. Prince, S.L. Arjun, G. Surya Raj and P. Gopalakrishnan, “Experimental Investigations on the Effects of Multicomponent Laser Boriding on steels,” Materials Today: Proceedings, vol. 5, pp. 25276-25284, 2018.
- [8] S. A. Rosas-Meléndez, M. Elías-Espinosa, J.A. Reyes-Retana and F. Cervantes-Sodi, “Friction and wear of borided AISI O1 steel with carbon nanomaterial deposit,” Materials Letters, vol. 282, pp. 1-4, 2021.
- [9] A. Erdoğan, “Investigation of high temperature dry sliding behavior of borided H13 hot work tool steel with nanoboron powder,” Surface & Coatings Technology, vol. 357, pp. 886-895, 2019.
- [10] A. P. Krelling, C. E. da Costa, J.C.G. Milan and E.A.S. Almeida, “Micro-abrasive wear mechanisms of borided AISI 1020 steel,” vol. 111, pp. 234-242, 2017.
- [11] I. Turkmen, E. Yalamac and M. Keddam, “Investigation of tribological behaviour and diffusion model of Fe2B layer formed by pack-boriding on SAE 1020 steel,” Surface & Coatings Technology”, vol. 377, pp. 1-12, 2019.
- [12] I. Türkmen and E. Yalamaç, “Growth of the Fe2B layer on SAE 1020 steel employed a boron source of H3BO3 during the powder-pack boriding method,” Journal of Alloys and Compounds, vol. 744, pp. 658-666, 2018.
- [13] A. Bendoumi, N. Makuch, R. Chegroune, M. Kulka, M. Keddam, P. Dziarski and D. Przestacki, “The effect of temperature distribution and cooling rate on microstructure and microhardness of laser re-melted and laser-borided carbon steels with various carbon concentrations,” Surface & Coatings Technology, vol. 387, pp. 1-20, 2020.
- [14] E. H. Sanchez and J. C. Valezquez, “Kinetics of Growth of Iron Boride Layers on a Low-Carbon Steel Surface,” Laboratory Unit Operations and Experimental Methods in Chemical Engineering-Chapter 3, pp. 37-55, IntechOpen, 2018.
- [15] İ. Güneş, “Investigation of Tribological Properties and Characterization of Borided AISI 420 and AISI 5120 Steels,” Trans Indian Inst Met, vol. 67, no. 3, pp. 359-365, 2014.
- [16] N. Barut, D. Yavuz and Y. Kayalı, “Borlanmış AISI 5140 ve AISI 420 Çeliklerinin Difüzyon ve Adhezyon Davranışlarının İncelenmesi,” Afyon Kocatepe Üniversitesi Fen ve Mühendislik Bilimleri Dergisi, vol. 14, pp. 1-8, 2014.
- [17] P. Juijerm, “Diffusion kinetics of different boronizing processes on martensitic stainless steel AISI 420,” Kovove Mater., vol. 52, pp. 232-236, 2014.
- [18] C. Martini, G. Palombarini and M. Carbucicchio,” Mechanism of thermochemical growth of iron borides on iron,” Journal of Materials Science, vol. 39, pp. 933-937, 2004.
- [19] Y. Kayali, “Investigation of the diffusion kinetics of borided stainless steels,” Physics of Metals and Metallography, vol. 114, pp. 161-168, 2013.
- [20]””https://www.uddeholm.com/app/uploads/sites/40/2017/11/mirrax esr-eng p.1506-1602.pdf, Erişim tarihi: 12.01.2021.
- [21] C. J. Scheuera, R. A. Fraga, R. P. Cardoso and S.F. Brunatto, “Effects Of Heat Treatment Condıtıons On Mıcrostructure And Mechanıcal Propertıes Of AISI 420 Steel,” 21º CBECIMAT - Congresso Brasileiro de Engenharia e Ciência dos Materiais, pp. 5857-5867, 2014.