Structure-properties relationship in TRIP type bainitic ferrite steel austempered at different temperatures

Bhadeshia, H. (2001). Bainite in Steels londone, IOM commercial Ltd.

Bleck, W. (2002). International Conference on TRIP-Aided High Strength Ferrous Alloys (pp. 13–23).

Bleck, W, Frehn, A, Ohlert, J (2001). In Niobium Science and Technology: Proceedings of the International Symposium Niobium 2001, Orlando, Florida, USA (pp. 727–752).

Chiang, J, Lawrence, B, Boyd, JD, Pilkey, AK. (2011). Effect of microstructure on retained austenite stability and work hardening of TRIP steels. Materials Science and Engineering, A 528, 4516–4521.

De Cooman, B, Barbé, L, Mahieu, J, Krizan, D, Samek, L, De Meyer, M. (2004). Mechanical properties of low alloy intercritically annealed cold rolled TRIP sheet steel containing retained austenite, Canadian metallurgical Q, 43(1), 13–24.

Demeyer, M, Vander, D, DeCoon, B. (1999). The influence of the substitutionof Si by Al on the properties of cold rolled C–Mn–Si TRIP steels. ISIJ International, 39, 813–22.

Dyson, D, Holmes, B. (1970). Effect of alloying additions on the lattice parameter austenite. Journal of Iron Steel Institute, 208, 469–474.

Emadoddin, E, Asmari1, H, Habibolah Zadeh, A. (2009). Formability evaluation of TRIP-aided steel sheets with different microstructures: polygonal ferrite and bainitic ferrite matrix. International Journal of Material Forming, 781–784.

Hausman, K. (2013). The influence of Nb on transformation behavior and mechanical properties of TRIPassisted bainitic-ferritic sheet steels. ,A 588, Materials Science and Engineering. Materials Science and Engineering, A588, 142–150.

Hojo, T, Kobayashi, J, Kajiyama, T, Sugimoto, K. (2010). Effects of alloying elements on impact properties of ultra high-strengthTRIP-aided bainitic ferrite steels. Jīn Shān Gāo Zhuān Jì Yào, No. 52, 9–16.

Hojo, T, Sugimoto, K, Mukai, Y, Ikeda, S. (2008). Effects of aluminum on delayed fracture properties of ultra high strength low alloy TRIP-aided steels. ISIJ International, 48 (No. 6), 824–829.

Huab, H, Xu, G, Wang, L, Xue, Z, Zhang, Y, Liu, G. (2015). The effects of Nb and Mo addition on transformation and properties in low carbon bainitic steels. Material Science and Design, 84, 95–99.

Jeong, W. (1994). Proc. of the Symp. on: High-strength Sheet Steels for the Automotive Ind., (p. 267). Baltimore.

Kim, S, Gil Lee, C, Lee, T, Oh, C. (2003). Effect of Cu, Cr and Ni on mechanical properties of 0.15 wt.% C TRIP-aided cold rolled steels. Scripta Materialia, 48, 539–544.

Maruyama, H. (1977). X-Ray measurement of retained austenite volume fraction. Journal Japanese Social Heat Treatment. Journal Japanese Social Heat Treatment, 17, 198–204.

Matsumura, O, Sakuma, Y, Ishii, Y, Zhao, J. (1992). Effects of Alloying Elements on Impact Properties of Ultra High-Strenght TRIP-Aided Bainitic Ferrite Steels. ISIJ International, 32, 1110–1116.

Ojima, Y, Shiroi, Y, Taniguchi, Y, Kato, K, SAE Tech. (1998). Application to Body Parts of High-Strength Steel Sheet Containing Large Volume Fraction of Retained Austenite, SAE Technical Paper 980954. Paper Series, (No. 980954), 39–50.

Saleh, M, Priestner, R. (2001). Retained austenite in dual-phase silicon steels and its effect on mechanical properties. Journal of Material Processing Technology, 113, 587–593.

Sugimoto, K, Iida, T, Sakaguchi, J, Kashima, T. (2000). Retained austenite characteristics and tensile properties in a TRIP type bainiric sheet steel. ISIJ International, 40(No. 9), 902–908.

Sugimoto, K, Kobayashi, M, Nagasaka, A, Hashimoto, S. (1995). Warm stretch-formability of TRIP-aided Dualphase Sheet Steels. ISIJ International, 35(11), 1407–1414.

Sugimoto, K, Kobayashi, M, Hashimoto, S. (1992). Ductility and Strain-Induced Transformation in a High-Strength Transformation-Induced Plasticity-Aided Dual-PhaseSteel. Metallurgical Transactions, A 23, 3085–3091.

Sugimoto, K, Muramatsu, T, Hashimoto, S, & Mukaid, Y. (2006). Formability of Nb bearing ultra high-strength TRIP-aided sheet steels. Journal of Materials Processing Technology, 177, 390–395.

Sugimoto, K, Murata, M, Muramatsu, T, Mukai, Y. (2007). Formability of C–Si–Mn–Al–Nb–Mo Ultra High-strength TRIP-aided Sheet Steels. ISIJ International, 47(No. 9), 1357–1362.

Sugimoto, K, Murata, M, Song, S. (2010). Formability of Al–Nb bearing ultra high-strength TRIP-aided sheet steels with bainitic ferrite and/or martensite matrix. ISIJ International, 50(No. 1), 162–168.

Sugimoto, K, Nagasaka, A, Kobayashi, M, Hashimoto, S. (1999). Effects of retained austenite parameters on warm stretch-flangeability in TRIP-aided dual-phase sheet steels. ISIJ International, 39, 56–63.

Sugimoto, K, Nakano, K, Song, S, Kashima, T. (2002). Retained austenite characteristics and stretchflangeability of high-strength low-alloy TRIP type bainitic sheet steels. ISIJ International, 42(No. 4), 450–455.

Sugimoto, K, Sato, S, Arai, G. (2010). Hot Forging of Ultra High-Strength TRIP-Aided Steel. Materials Science Forum, 638-642, 3074–3079.

Sugimoto, K, Sun, X, Kobayashi, M, Haga, T, & Shirasawa, H. (1997). Fatique properties of TRIP-aided dual phase sheet steel Transactions of the Japan Society of Mechanical Engineering, 63A, 717.

Tamura, I (1970). Steel Material Study on the Strength. (p. 40). Tokyo: Nikkan Kogyo Shinbun Ltd.

Zhao, Z, Yin, H, Zhao, A, Gong, Z, He, J, Tong, T, Ju, H. (2014). The influence of the austempering temperature on the transformation behavior and properties of ultra-high-strength TRIP-aided bainitic ferritic sheet steel. Materials Science & Engineering, A 613, 8–16a.