Abstract
Metal is the most important material in modern industry, widely used in agriculture, industry, national defense industry, and other departments. Since the selection of materials for most mechanical equipments is based on its mechanical performance, the mechanical properties of metals should be first known. This section will focus on the plasticity and deformation resistance of metal materials and their influencing factors.
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References
Ning MA, Ping HU, Shuji ZAI, Wei GUO (2009) Technology and application of hot forming of high strength steel. Automobile Technol Mater 10(12):28–30 (In Chinese)
Ning MA, Ping HU, Wei GUO (2010) Experiments and analysis of relations among heat, stress and transformation of boron steel for hot forming. Trans Mater Heat Treat 12(5):33–40 (In Chinese)
Frank J, Mark E, Mohan R et al (2009) Evolution of phases, microstructure, and surface roughness during heat treatment of aluminized low carbon steel. Metall Mater Trans A 6:1554–1563
Fan DW, Kim MS (2008) Physical metallurgy of hot press forming ultra high strength steel. Mater Sci Technol 22(4):1710–1721
Lorenz D, Roll K (2004) Simulation of hot stamping and quenching of boron alloyed steel. In: 7th International ESAFORM Conference on material forming, 28–30 Apr 2004, Trondheim, Norway, pp 659–662
Kapadia BM, Brown RM, Murphy WJ (1968) The influence of nitrogen, titanium, and zirconium on the boron hardenability effect in constructional alloy steels. Trans Metall Soc AIME 242(8):1689–1694
Eriksson M, Oldenburg M, Somani MC, Karjalainen LP (2002) Testing and evaluation of material data for analysis of forming and hardening of boron steel components. Modell Simul Mater Sci Eng 10:277–294
Ning MA, Ping HU, Kangkang YAN, Wei GUO, Xiangbin MENG, Shuji ZHAI (2010) Research on boron steel for hot forming and its application. J Mech Eng 46(14):177–181 (In Chinese)
Ma N, Hu P, Shen GZ et al (2010) Modeling, testing and numerical simulation on hot forming. AIP Conference Proceedings, Plenary lecture of NUMIFORM2010, pp 18–27
Ma N, Hu P, Guo W et al (2009) Feasible methods applied to the design and manufacturing process of hot forming. IDDRG2009 conference, Golden, CO USA, pp 835–843
Grange K, Kiefer J (1941) The transformation of austenite by continuous cooling. Trans ASM 29:85–115
Zhuang L, Zhaoji W, Jingzhi W et al (1996) The numerical simulation of heat treatment process. Science Press, Beijing (In Chinese)
Garcia Aranda L, Chastel Y, Fernández Pascual J, Dal Negro T (2002) Experiments and simulation of hot stamping of quenchable steels. Adv Technol Plast 2:1135–1140
Naderi M (2007) Hot stamping of ultra high strength steels. Doctoral Theses, RWTH Aachen
Mingtu MA (2008) Car lightweight and high strength steel advanced processing forming technique. Proceedings of international seminar on automobile body steel technology, 2008, pp 28–45 (In Chinese)
Li WANG, Xiong fei YANG, Jiang xin LU (2006) Development of high strength steel sheets for lightweight automobile. Gangtie 41(9):1–8 (In Chinese)
Weili XU, Shurong GUAN, Jian AI (2009) Key equipment and core technology of hot stamping. World Iron Steel 2:30–33 (In Chinese)
Keeler Stuart P (1968) Circular grid system-a valuable aid for evaluating sheet metal formability. SAE Trans 680092: 371–379
Goodwin Gorton M (1968) Application of strain analysis to sheet metal forming problems in the press shop. SAE Trans 680093:380–387
Nemat-Nasser S (1999) Experimentally-based micromechanical modeling of metal plasticity with homogenization form micro-to-macro-scale properties. In: IUTAM symposium on micro- and macrostructural aspects of thermoplasticity, pp 101–113
Johnson GR, Cook WH (1983) A constitutive model and data for metals subjected to large strains, high strain-rates and high temperature. In: The 7th symposium on ballistic, pp 541–547
Tong L, Stahel S, Hora P (2005) Modeling for the FE simulation of warm metal forming processes. In: The 6th international conference and workshop on numerical simulation of 3D sheet metal forming processes, pp 625–629
Ghosh A, Kikuchi N (1988) Finite element formulation for the simulation of hot sheet metal forming processes. Int J Eng Sci 26(2):143–161
Molinari AM, Ravichandran G (2005) Constitutive modeling of the high-strain-rate deformation in metals based on the evolution of an effective microstructural length. Mech Mater 37:737–752
Merklein M, Lechler J (2008) Determination of material and process characteristics for hot stamping processes of quenchenable ultra high strength steels with respect to a FE-based process design. SAE world congress: innovations in steel and applications of advanced high strength steels for automotive structures, paper no. 2008-0853
Turetta A, Ghiotti A, Bruschi S (2006) Investigation of 22MnB5 formability in hot stamping operations. J Mater Process Technol 177:396–400
Hoffmann H, So H, Steinbeiss H (2007) Design of hot stamping tools with cooling system. Ann CIRP 56(1):269–272
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Hu, P., Ma, N., Liu, Lz., Zhu, YG. (2013). The Basic Mechanical Properties and Experimental Verification for Hot Forming Steel. In: Theories, Methods and Numerical Technology of Sheet Metal Cold and Hot Forming. Springer Series in Advanced Manufacturing. Springer, London. https://doi.org/10.1007/978-1-4471-4099-3_4
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DOI: https://doi.org/10.1007/978-1-4471-4099-3_4
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