摘要
利用连续镀锌模拟设备,研究了微合金化元素Nb、V和V-N加入到低碳高强(980级)双相钢后组织与性能的变化。在基本成分基础上,设计了不同含量的V或Nb、采用高N或正常N含量的钢,经过不同的热浸镀锌(GI)、合金化镀锌(GA)和超快冷处理。此外,还利用石英管炉对模拟镀锌后的钢板进行热处理。结果表明,马氏体—贝氏体—铁素体各相比例受到不同微合金化元素加入量的强烈影响,但是各相强度影响较小。在小于0.1%C^1.75%Mn钢中实测抗拉强度达到1 100 MPa、同时具有良好的塑性和加工硬化性能。
A study is being conducted of additions of the microalloying elements Nb,V and V-N to a low carbon,high-strength( 980 grade) Dual-Phase steel that was processed using a CGL simulation. In this study,compositions with a common base but containing various additions of V or Nb with or without high N were designed and subjected to Gleeble simulations of different galvanizing( GI),galvannealing( GA) and super cooling processing. These experiments were supplemented with additional heat treatments performed using a quartz filament furnace. The results revealed that the phase balance( martensite-bainite-ferrite)was strongly influenced by the different microalloying additions,while the strengths of each phase were somewhat less affected. UTS levels of 1 100 MPa,along with good levels of ductility and work hardening,were measured in steels containing less than 0. 1% C and 1. 75% Mn. The results of this program will be presented and discussed.
出处
《钢铁钒钛》
CAS
北大核心
2015年第1期73-76,共4页
Iron Steel Vanadium Titanium
关键词
微合金化双相钢
强度
塑性
加工硬化
n值
屈强比
临界退火
热浸镀锌
合金化镀锌
microalloyed dual-phase steels
high strength
ductility
work hardening
n-values
yield / tensile ration
intercritical annealing
ga