Effect of plastic deformation rate at room temperature on structure and mechanical properties of high-Mn austenitic Mn-Al-Si 25-3-3 type steel

• Autorzy: Borek W. , Lis M. , Gołombek K. , Sakiewicz P. , Piotrowski K.

Identyfikatory

DOI

10.5604/01.3001.0013.1989

• Języki publikacji: EN

Abstrakty

EN

Purpose: The aim of the paper is to determine influence of plastic deformation rate at room temperature on structure and mechanical properties of high-Mn austenitic Mn-Al-Si 25-3-3 type steel tested at room temperature. Design/methodology/approach: Mechanical properties of tested steel was determined using Zwick Z100 static testing machine for testing with the deformation speed equal 0.008 s-1, and RSO rotary hammer for testing with deformation speeds of 250, 500 and 1000s-1. The microstructure evolution samples tested in static and dynamic conditions was determined in metallographic investigations using light microscopy as well as X-ray diffraction. Findings: Based on X-ray phase analysis results, together with observation using metallographic microscope, it was concluded, that the investigated high-Mn X13MnAlSiNbTi25-3-3 steel demonstrates austenitic structure with numerous mechanical twins, what agrees with TWIP effect. It was demonstrated, that raise of plastic deformation rate produces higher tensile strength UTS and higher conventional yield point YS0.2. The UTS strength values for deformation rate 250, 500 and 1000 s-1 grew by: 35, 24 and 31%, appropriately, whereas in case of YS0.2 these were: 7, 74 and 130%, accordingly, in respect to the results for the investigated steel deformed under static conditions, where UTS and YS0.2 values are 1050 MPa and 700 MPa. Opposite tendency was observed for experimentally measured uniform and total relative elongation. Homogeneous austenitic structure was confirmed by X-ray diffractometer tests. Research limitations/implications: To fully describe influence of strain rates on structure and mechanical properties, further investigations specially with using transmission electron microscope are required. Practical implications: Knowledge about obtained microstructures and mechanical properties results of tested X13MnAlSiNbTi25-3-3 steel under static and dynamic conditions can be useful for the appropriate use of this type of engineering material in machines and equipment susceptible to static or dynamic loads. Originality/value: The influence of plastic deformation at room temperature under static and dynamic conditions of new-developed high-manganese austenitic X13MnAlSiNbTi25-3-3 steels were investigated.

Słowa kluczowe

EN

high-Mn steel; TWIP type steel; plastic deformation; twinning; dynamic deformation; structure; mechanical properties

PL

stal wysokomanganowa; stal TWIP; odkształcenie plastyczne; bliźniakowanie; odkształcenie dynamiczne; struktura; własności mechaniczne

• Wydawca: International OCSCO World Press
• Czasopismo: Archives of Materials Science and Engineering
• Rocznik: 2019
• Tom: Vol. 96, nr 1
• Strony: 22--31
• Opis fizyczny: Bibliogr. 41 poz.

Twórcy

autor

Borek W.

• Institute of Engineering Materials and Biomaterials, Faculty of Mechanical Engineering, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Lis M.

• Institute of Engineering Materials and Biomaterials, Faculty of Mechanical Engineering, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Gołombek K.

• Institute of Engineering Materials and Biomaterials, Faculty of Mechanical Engineering, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Sakiewicz P.

• Institute of Engineering Materials and Biomaterials, Faculty of Mechanical Engineering, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland

autor

Piotrowski K.

• Department of Chemical Engineering and Process Design, Faculty of Chemistry, Silesian University of Technology, ul. Marcina Strzody 9, 44-100 Gliwice, Poland

Bibliografia

• [1] L.A. Dobrzański, Fundamentals of materials science and metallurgy, WNT, Warszawa, 2003 (in Polish).
• [2] M. Ambroziński, S. Polak, Z. Gronostajski, R. Kuziak, W. Chorzępa, M. Pietrzyk, Numerical simulation of crash test accounting for the strain hardening in the manufacturing process of energy- absorbing part in the car body, Mechanic 88/2 (2015) 92-97 (in Polish).
• [3] L. Sozańska-Jędrasik, J. Mazurkiewicz, W. Borek, K. Matus, Carbides analysis of the high strength and low density Fe-Mn-Al-Si steels, Archives of Metallurgy and Materials 63/1 (2018) 265-276.
• [4] R. Kuziak, R. Kawalla, S. Waengler, Advanced high strength steels for automotive industry, Archives of Civil and Mechanical Engineering 8/2 (2014) 103-117.
• [5] M. Askari-Paykani, H.R. Shahverdi, R. Miresmaeili, First and third generations of advanced high-strength steels in a FeCrNiBSi system, Journal of Materials Processing Technology 238 (2016) 383-394.
• [6] J.-H. Schmitt, T. lung, New developments of advanced high-strength steels for automotive applications, Comptes Rendus Physique 19/8 (2018) 641-656.
• [7] B. Fu, W.Y. Yang, Y.D. Wang, L.F. Li, Z.Q. Sun, Y. Ren, Micromechanical behavior of TRIP-assisted multiphase steels studied with in situ high-energy X-ray diffraction, Acta Materialia 76 (2014) 342-354.
• [8] G. Rosenberg, I. Sinaiova, L. Juhar, Effect of microstructure on mechanical properties of dual phase steels in the presence of stress concentrators, Materials Science and Engineering A 582 (2013) 347-358.
• [9] J. Senkara, Contemporary car body steels for automotive industry and technological guidelines of their pressure welding, Welding Review 81/11 (2009) 3-7.
• [10] T.Y. Liu, P. Yang, L. Meng, F.Y. Lu, Influence of austenitic orientation on martensitic transformations in a compressed high manganese steel, Journal of Alloys and Compounds 509/33 (2011) 8337-8344.
• [11] K.T. Park, G. Kim, S.K. Kim, S.W. Lee, S.W. Hwang, C.S. Lee, On the transitions of deformation modes of fully austenitic steels at room temperature, Metals and Materials International 16/1 (2010) 1-6.
• [12] A. Tomaszewska, Research of properties of X20MnA117-3 steel, Metallurgist 78/8 (2011) 674-677 (in Polish).
• [13] X. Li, L. Chen, Y. Zhao, R.D.K. Misra, Influence of manganese content on £-/a'-martensitic transformation and tensile properties of low-C high-Mn TRIP steels, Materials and Design 142 (2018) 190-202.
• [14] L. Chen, Y. Zhao, X. Qin, Some aspects of high manganese twinning-induced plasticity (TWIP) steel, a review, Acta Metallurgica Sinica (English Letters) 26/1 (2013) 1-15.
• [15] S. Curtze, V. Kuokkala, Dependence of tensile deformation behavior of TWIP steels on stacking fault energy, temperature and strain rate, Acta Materialia 589/5 (2010) 5129-5141.
• [16] B.C. De Cooman, K.G. Chin, J. Kim, High Mn TWIP steels for automotive applications, in: M. Chiaberge (Ed.), New Trends and Developments in Automotive System Engineering, No. 1, Intech, Rijeka, 2011, 101-128.
• [17] L.A. Dobrzanski, W. Borek, J. Mazurkiewicz, Influence of high strain rates on the structure and mechanical properties of high-manganese austenitic TWIP-type steel, Materialwissenschaft Und Werkstofftechnik 47/5-6 (2016) 428-435.
• [18] W. Borek, T. Tanski, Z. Jonsta, P. Jonsta, L. Cizek, Structure and mechanical properties of high-Mn TWIP steel after their thermo-mechanical and heat treatments, Proceeedings of the 4th International Conference on Metallurgy and Materials "METAL 2015", 2,2015,307-313.
• [19] J.D. Yoo, K.-T. Park, Microband-induced plasticity in a high Mn-Al.-C light steel, Materials Science and Engineering A 496/1 (2008) 417-424.
• [20] S. Chen, R. Rana, A. Haidar, R.K. Ray, Current state of Fe-Mn-Al-C low density steels, Progress in Materials Science 89 (2017) 345-391.
• [21] J. Moon, S.J. Park, J.H. Jang, T.H. Lee, C.H. Lee, H.U. Hong, H.N. Han, J. Lee, B.H. Lee, C. Lee, Investigations of the microstructure evolution and tensile deformation behavior of austenitic Fe-Mn-Al-C lightweight steels and the effect of Mo addition, Acta Materialia 147 (2018) 226-235.
• [22] A. Grajcar, R. Kuziak, W. Zalecki, Third generation of AHSS with increased fraction of retained austenite for the automotive industry, Archives of Civil and Mechanical Engineering 12/3 (2012) 334-341.
• [23] W.W. Sun, Y.X. Wu, S.C. Yang, C.R. Hutchinson, Advanced high strength steel (AHSS) development through chemical patterning of austenite, Scripta Materialia 146 (2018) 60-63.
• [24] M.B. Jabłońska, Structure and properties of austenitic high-manganese steel reinforced due to mechanical twins in dynamic deformation processes, Silesian University of Technology Publishing House, Gliwice, 2016 (in Polish).
• [25] O. Bouaziz, S. Allain, C.P. Scott, P. Cugy, D. Barbier, High manganese austenitic twinning induced plasticity steels: A review of the microstructure properties relationships, Current Opinion in Solid State and Materials Science 15/4 (2011) 141-168.
• [26] S.W. Bhero, B. Nyembe, K. Lentsoana, Common failures of hadfield steel in application, Proceednigs of the International Conference on Mining, Mineral Processing and Metallurgical Engineering "ICMMME'2014", Johannesburg, 2014, 17-19.
• [27] S. Kołodziej, Influence of martensitic transformation on the structure and anisotropic properties of high manganese TWIP plastically deformable steels, Silesian University of Technology, Gliwice, 2016 (in Polish).
• [28] S. Wenwen, I. Tobias, W. Bleck, Control of strain hardening behavior in high-Mn austenitic steels, Acta Metallurgica Sinica (English Letters) 27/3 (2014) 546-555.
• [29] A. Bronz, V. Deminskaya, L. Kaputkina, V. Kindop, D. Kremyansky, Structure and strength cast high aluminum and manganese of iron alloys with a high carbon content, National University of Science and Technology, 36-39.
• [30] K. Hansoo, S. Dong-Woo, J.K. Nack, Fe-Al-Mn-C lightweight structural alloys: a review on the microstructures and mechanical properties, Science and Technology of Advanced Materials 14/1 (2013) 14205.
• [31] M.B. Jabłońska, A. Śmiglewicz, G. Niewielski, The effect of strain rate on the mechanical properties and microstructure of the high-Mn steel after dynamic deformation tests, Archives of Metallurgy and Materials 60/2 (2015) 577-580.
• [32] E. Mazancova, I. Schindler, K. Mazanec, Stacking fault energy analysis from point of view of plastic deformation response of the TWIP and TRIPLEX alloys, Proceedings of the 18th International Conference on Metallurgy and Materials "Metal 2009", Hradec nad Moravici, 2009.
• [33] X. Tian, Y. Zhang, Effect of Si content on the stacking fault energy in y-Fe-Mn-Si-C alloys: Part II. Thermodynamic estimation, Materials Science and Engineering A 516/2 (2009) 78-83.
• [34] O. Grässel, L. Krüger, G. Frommeyer, L. Meyer, High strength Fe-Mn-(A1, Si) TRIP/TWIP steels development - properties - application, International Journal of Plasticity 16/10 (2000) 1391-1409.
• [35] L.A. Dobrzański, W. Borek, J. Mazurkiewicz, Mechanical properties of high-Mn austenitic steel tested under static and dynamic conditions, Archives of Metallurgy and Materials 61/2 (2016) 725-730.
• [36] A. Smiglewicz, M.B. Jabłońska, K. Rodak, Stacking fault energy and mechanical twinning in the high-manganese X30MnAlSi26-4-3 steel, Metallurgist 82/8 (2015) 472-474 (in Polish).
• [37] K.-T. Park, K.G. Jin, S.H. Han, S.W. Hwang, K. Choi, C.S. Lee, Stacking fault energy and plastic deformation of fully austenitic high manganese steels: Effect of A1 addition, Materials Science and Engineering A 527/16 (2010) 3651-3661.
• [38] L.A. Dobrzanski, A. Grajcar, W. Borek, Microstructure evolution of high-manganese steel during the thermomechanical processing, Archives of Materials Science and Engineering 37/2 (2009) 69-76.
• [39] G. Frommeyer, U. Brux, P. Neumann, Supra-ductile and high-strength manganese-TRIP/TWIP steels for high energy absorption purposes, ISIJ International 43/3 (2003) 438-446.
• [40] P.S. Kusakin, R.O. Kaibyshev, High-Mn twinning- induced plasticity steels: Microstructure and mechanical properties, Reviews on Advanced Materials Science 44/4 (2016) 326-360.
• [41] S.G. Hong, S.B. Lee, Mechanism of dynamic strain aging and characterization of its effect on the low-cycle fatigue behavior in type 316L stainless steel, Journal of Nuclear Materials 340/2 (2005) 307-314.

Uwagi

PL

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).