Investigation of the Tribological and Mechanical Properties of Boron Steels in Terms of Potential Usage in Agricultural Applications
Year 2021,
, 431 - 438, 01.06.2021
Fatih Bozkurt
,
Fatih Hayati Çakır
,
Ümit Er
Abstract
The usage amounts of boron steels are increasing gradually, especially in industrial applications requiring high wear resistance. One of the usages of this type of steel is tillage tools, which are working in harsh conditions. Prominent desired properties for materials that face the soil in agricultural machining are hardness, abrasive wear resistance, impact toughness. In this study, the tribological and mechanical properties of 30MnB5 boron steel used in agricultural mechanization are investigated, applying three different heat treatment procedures. The impact strength, hardness and abrasive wear resistance of the as supplied, quenched and quenched cryo treated-tempered samples are evaluated. It was observed that the quenching is an essential heat treatment for usage of boron steel in agricultural field. The tempering reduces hardness of the specimen and cyrogenic treatment and tempering increased the impact toughness.
References
- [1] Misra A., Finnie I., “A Review of the Abrasive Wear of Metals”, Journal of Engineering Materials and Technology, 104(2): 94–101, (1982)
- [2] Er Ü., Par B., “Wear of plowshare components in SAE 950C steel surface hardened by powder boriding”, Wear, 261( 3–4): 251–255, (2006)
- [3] Er B., “Abrasive Wear Behaviour of Hardened AISI 51B60H Boron Steel”. ISAS 2018 – 1st International Symposium on Innovative Approaches in Scientific Studies, Antalya, Turkey, 297-301, (2018)
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- [5] Er Ü., “The abrasive wear behaviour of boron steels”, Eskişehir Osmangazi Üniversitesi Mühendislik ve Mimarlık Fakültesi Dergisi, 17(2): 59–70, (2004)
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- [9] Gupta A.K., Jesudas D.M., Das P.K., Basu K., “Performance Evaluation of Different Types of Steel for Duck Foot Sweep Application”, Biosystems Engineering, 88(1): 63–74, (2004)
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- [17] Koneshlou M., Meshinchi K. A., Khomamizadeh F., “Effect of cryogenic treatment on microstructure, mechanical and wear behaviors of AISI H13 hot work tool steel”, Cryogenics, 51(1): 55–61, (2011)
- [18] Bensely A., Prabhakaran A., Mohan L.D., Nagarajan G., “Enhancing the wear resistance of case carburized steel (En 353) by cryogenic treatment”, Cryogenics, 45(12): 747–754, (2005)
- [19] Liu H., Wang J., Yang H., Shen B., “Effects of cryogenic treatment on microstructure and abrasion resistance of CrMnB high-chromium cast iron subjected to sub-critical treatment”, Materials Science and Engineering: A, 478(1–2): 324–328, (2008)
- [20] Kaya E., Ulutan M., “Tribological and Mechanical Properties of Deep Cryogenically Treated Medium Carbon Micro Alloy Steel”, Metals and Materials International, 23(4): 691-698, (2017)
- [21] Çakır F. H., Çelik O. N., “The effects of cryogenic treatment on the toughness and tribological behaviors of eutectoid steel”, Journal of Mechanical Science and Technology, 31(7): 3233-3239, (2017)
- [22] Özer M., “The Effect of Deep Cryogenic Processing and Tempering Heat Treatment of AISI H13 Tool Steel on Microstructure, Hardness and Impact Energy”, Gazi Üniversitesi, Fen Bilimleri Dergisi, Part C: Tasarım ve Teknoloji, 7(3): 688-699, (2019)
- [23] Singh T. P., Singla A. K., Singh J., Singh K., Gupta M. K., Ji Hansong., Song Q., Liu Z., Pruncu C. I., “Abrasive Wear Behavior of Cryogenically Treated Boron Steel (30MnCrB4) Used for Rotavator Blades”, Materials, 13(436): 1-16, (2020)
- [24] Altamirano G., Mejia I., Hernandez-Exposito A., Cabrera J. M., “Effect of boron on the continuous cooling transformation kinetics in a low carbon advanced ultra-high strength steel (A-UHSS)”, MRS Online Proceeding Library Archive, 1485: 83-88, (2012)
- [25] Thelning K. E., “Steel and Its Heat Treatment, 2nd Edition”, Butterworth-Heinemann, (2013)
Investigation of the Tribological and Mechanical Properties of Boron Steels in Terms of Potential Usage in Agricultural Applications
Year 2021,
, 431 - 438, 01.06.2021
Fatih Bozkurt
,
Fatih Hayati Çakır
,
Ümit Er
Abstract
Boron steels are increasingly used material especially in industrial applications requiring high wear resistance. The main area of usage of this type of steel is tillage tools which are working in harsh conditions. In addition to the abrasive wear resistance, impact toughness is also required properties. In this study, the effect of cryogenic treatment on 30MnB5 boron steel used in agricultural mechanization is investigated in terms of the tribological and mechanical properties. Charpy impact test, the hardness and the abrasive wear tests are performed on untreated, heat treated and cryogenically treated of 30MnB5 steel. It is observed that the hardness of the specimen is slightly decreased but impact toughness is increased for the quenched and cryo treated specimen in comparison to conventionally heat-treated specimen.
References
- [1] Misra A., Finnie I., “A Review of the Abrasive Wear of Metals”, Journal of Engineering Materials and Technology, 104(2): 94–101, (1982)
- [2] Er Ü., Par B., “Wear of plowshare components in SAE 950C steel surface hardened by powder boriding”, Wear, 261( 3–4): 251–255, (2006)
- [3] Er B., “Abrasive Wear Behaviour of Hardened AISI 51B60H Boron Steel”. ISAS 2018 – 1st International Symposium on Innovative Approaches in Scientific Studies, Antalya, Turkey, 297-301, (2018)
- [4] Yu H. J., Bhole S. D., “Development of a prototype abrasive wear tester for tillage tool materials”, Tribology International, 23(5): 309–316, (1990)
- [5] Er Ü., “The abrasive wear behaviour of boron steels”, Eskişehir Osmangazi Üniversitesi Mühendislik ve Mimarlık Fakültesi Dergisi, 17(2): 59–70, (2004)
- [6] Çakır F. H., Çelik O. N., “Effect of Isothermal Bainitic Quenching on Rail Steel Impact Strength and Wear Resistance”, Metal Science and Heat Treatment, 59(5–6): 289–293, (2017)
- [7] Pyndak V. I., Novikov A. E., “Tribotechnical and Energy Assessment of Parts of Working Members of Cultivating Machines After Carburizing and Laser Hardening”, Metal Science and Heat Treatment, 58(3–4): 226–230, (2016)
- [8] Foley A. G., Lawton P.J., Barker A.W., McLees V.A., “The use of alumina ceramic to reduce wear of soil-engaging components”, Journal of Agricultural Engineering Research, 30: 37–46, (1984)
- [9] Gupta A.K., Jesudas D.M., Das P.K., Basu K., “Performance Evaluation of Different Types of Steel for Duck Foot Sweep Application”, Biosystems Engineering, 88(1): 63–74, (2004)
- [10] Quirke S., Scheffler O., Allen C., “An evaluation of the wear behaviour of metallic materials subjected to soil abrasion”, Soil and Tillage Research, 11(1): 27–42, (1988)
- [11] Arıkan M. M., Başman G., “Otomotiv endüstrisi için yeni çelik ürünler ve özellikleri”, Uluslararası Demir-Çelik Sempozyumu, Karadeniz Ereğli Zonguldak, Turkey, 387-400, (2001)
- [12] Altamiran G., Mejía I., Hernández-Expósito A., Cabrera J.M., “Effect of boron on the continuous cooling transformation kinetics in a low carbon advanced ultra-high strength steel (A-UHSS)”, Materials Research Society, 1485: 83–88, (2012)
- [13] Hernandez S., Hardell J., Winkelmann H., Ripoll M.R., Prakash B., “Influence of temperature on abrasive wear of boron steel and hot forming tool steels”, Wear, 338–339: 27–35, (2015)
- [14] Bialobrzeska B., Kostencki P., “Abrasive wear characteristics of selected low-alloy boron steels as measured in both field experiments and laboratory test”, Wear, 328–329: 149–159, (2015)
- [15] Hardell J., Kassfeldt E., Prakash B., “Friction and wear behaviour of high strength boron steel at elevated temperatures of up to 800°C”, Wear, 264(9–10): 788–799, (2008)
- [16] Zhirafar S., Rezaeian A., Pugh M., “Effect of cryogenic treatment on the mechanical properties of 4340 steel”, Journal of Materials Processing Technology, 186(1–3): 298–303, (2007)
- [17] Koneshlou M., Meshinchi K. A., Khomamizadeh F., “Effect of cryogenic treatment on microstructure, mechanical and wear behaviors of AISI H13 hot work tool steel”, Cryogenics, 51(1): 55–61, (2011)
- [18] Bensely A., Prabhakaran A., Mohan L.D., Nagarajan G., “Enhancing the wear resistance of case carburized steel (En 353) by cryogenic treatment”, Cryogenics, 45(12): 747–754, (2005)
- [19] Liu H., Wang J., Yang H., Shen B., “Effects of cryogenic treatment on microstructure and abrasion resistance of CrMnB high-chromium cast iron subjected to sub-critical treatment”, Materials Science and Engineering: A, 478(1–2): 324–328, (2008)
- [20] Kaya E., Ulutan M., “Tribological and Mechanical Properties of Deep Cryogenically Treated Medium Carbon Micro Alloy Steel”, Metals and Materials International, 23(4): 691-698, (2017)
- [21] Çakır F. H., Çelik O. N., “The effects of cryogenic treatment on the toughness and tribological behaviors of eutectoid steel”, Journal of Mechanical Science and Technology, 31(7): 3233-3239, (2017)
- [22] Özer M., “The Effect of Deep Cryogenic Processing and Tempering Heat Treatment of AISI H13 Tool Steel on Microstructure, Hardness and Impact Energy”, Gazi Üniversitesi, Fen Bilimleri Dergisi, Part C: Tasarım ve Teknoloji, 7(3): 688-699, (2019)
- [23] Singh T. P., Singla A. K., Singh J., Singh K., Gupta M. K., Ji Hansong., Song Q., Liu Z., Pruncu C. I., “Abrasive Wear Behavior of Cryogenically Treated Boron Steel (30MnCrB4) Used for Rotavator Blades”, Materials, 13(436): 1-16, (2020)
- [24] Altamirano G., Mejia I., Hernandez-Exposito A., Cabrera J. M., “Effect of boron on the continuous cooling transformation kinetics in a low carbon advanced ultra-high strength steel (A-UHSS)”, MRS Online Proceeding Library Archive, 1485: 83-88, (2012)
- [25] Thelning K. E., “Steel and Its Heat Treatment, 2nd Edition”, Butterworth-Heinemann, (2013)