Abstract
The steel micro-alloyed with ferrovanadium nitride has extremely superior properties that make it widely utilized in structural components, construction and aircraft. The conventional methods for synthesizing ferrovanadium nitride include nitridation of pure ferrovanadium alloy or carbothermal nitridation of metallic oxides, using nitrogen or ammonia gas as nitrogen sources. In this study, ferrovanadium nitride (FeV45N) was prepared by direct reduction and nitridation of the corresponding metal oxides with ammonia as the reductant and nitrogen source. This method avoids the introduction of other impurity elements, except the negligible trace elements accompanied with the raw materials. The thermodynamics of the reduction and nitridation process were initially analyzed. During the subsequent ammonia reduction process, the FeV45N powders were successfully obtained at 1273 K for 6 h. The obtained powders were pressed into cylindrical briquettes by hot pressing (HP) at 1473 K for 1 h in vacuum. In the investigation, the X-ray diffraction and morphological analysis of the products was also carried out, and the reaction mechanisms were discussed in detail. The nitrogen content of the final product can reach 11.85 wt. %, and the residual oxygen content can be reduced to 0.25 wt. %. By sintering, the density of the alloy can reach 5.92 g/cm3.
Highlights
High-strength low-alloy (HSLA) steel has attracted much attention in industry due to its superior properties and economic benefits [1,2,3]
Reduction roasting was conducted as a function of temperature (4 h) and to some extent
The phase transformation during the entire reaction process proceeded in the following order: When the temperature was lower than 1073 K, NH3 reacted with Fe2O3 to form Fe and Fe4N directly
Summary
High-strength low-alloy (HSLA) steel has attracted much attention in industry due to its superior properties and economic benefits [1,2,3]. The superior performance of HSLA steel mainly accounts for microalloying with carbide- and nitride-forming metals (V, Nb, Al, Ti, etc.). The advantages of nitrogen are related to grain refinement, austenite stabilization, formation of nitrides and carbonitrides with extremely high structural hardness and significant increasing of strength, without restriction of ductility [3,4]. Among these microalloying additives, HSLA steel microalloyed with vanadium and nitrogen exhibits particular economic superiority. Nitrogen is capable of being introduced into the melt by blowing
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