Study on the Mechanism of Strengthening and Toughening Effect
of Titanium Addition on HSLA Steel
مطالعهی مکانیزم استحکامبخشی و اثر چقرمهسازی افزودن تیتانیم روی فولاد HSLA
ABSTRACT
Based on the determination of load variation against deflection by means of Instrumented Charpy Impact testing, the impact energy distribution of the High Strength Low Alloy (HSLA) steel containing Nb, Ni and Ti for pressure vessels at low temperature has been quantitatively studied. The total impact energy Et could be divided into two parts, Ei and Ep. Ei is related to the base strength of the material in terms of the grain size and alloy addition, which is also found to be less influenced by the holding time of normalization process at 910℃. Whereas, Ep of Ni-Nb-Ti HSLA steel is strongly linked to the period of holding time. Thermodynamic kinetic investigation was carried out to study the strengthening mechanism with metallurgical microstructure analysis.
ABSTRACT
The addition of small amounts of Nb, Ti or V singly or in combination has been the key to producing high strength low alloy (HSLA) steels with greatly improved mechanical properties. Such microalloyed HSLA steels are now commonplace in a huge variety of applications. The combinations of strength, toughness and formability that are possible are directly related to the way in which the steel is processed from the as- cast slab (usually) to the final plate or strip dimensions. The effects of microalloying result principally from three main effects on the austenite to ferrite transformation. Firstly, the microalloying additions form precipitates in both austenite and ferrite; this factor alone can be exploited in various ways to control the microstructure, hence mechanical properties, of the steel. Secondly, although present in relatively small quantities,there are discernible effects on ferrite transformations in terms of the hardenability of the steel. Finally, there are interactions between the various deformation sequences used in steel production and the presence of microalloying elements as solutes or precipitates which can be exploited to control microstructure. The interactions between processing, microstructural development and the effect of microalloying additions on the austenite ferrite transformations are the topic of this chapter. A brief history of the use of microalloying is also given as is some indication of the range of mechanical properties that result from the current understanding of the role of microalloying additions.
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